// Copyright (c) Microsoft Corporation. All Rights Reserved. See License.txt in the project root for license information.

module FSharp.Compiler.AbstractIL.IL

open FSharp.Compiler.IO
open Internal.Utilities.Library

#nowarn "49"
#nowarn "343" // The type 'ILAssemblyRef' implements 'System.IComparable' explicitly but provides no corresponding override for 'Object.Equals'.
#nowarn "346" // The struct, record or union type 'IlxExtensionType' has an explicit implementation of 'Object.Equals'. ...

open System
open System.Diagnostics
open System.Collections
open System.Collections.Generic
open System.Collections.Concurrent
open System.Collections.ObjectModel
#if !FABLE_COMPILER
open System.Linq
#endif
open System.Reflection
open System.Text
open System.Threading

open FSharp.Compiler.AbstractIL.Diagnostics
open Internal.Utilities

let logging = false

let _ =
    if logging then
        dprintn "* warning: Il.logging is on"

/// A little ugly, but the idea is that if a data structure does not
/// contain lazy values then we don't add laziness. So if the thing to map
/// is already evaluated then immediately apply the function.
let lazyMap f (x: InterruptibleLazy<_>) =
    if x.IsValueCreated then
        notlazy (f (x.Force()))
    else
        InterruptibleLazy(fun _ -> f (x.Force()))

[<RequireQualifiedAccess>]
type PrimaryAssembly =
    | Mscorlib
    | System_Runtime
    | NetStandard

    member this.Name =
        match this with
        | Mscorlib -> "mscorlib"
        | System_Runtime -> "System.Runtime"
        | NetStandard -> "netstandard"

    static member IsPossiblePrimaryAssembly(fileName: string) =
        let name = System.IO.Path.GetFileNameWithoutExtension(fileName)

        String.Equals(name, "System.Runtime", StringComparison.OrdinalIgnoreCase)
        || String.Equals(name, "mscorlib", StringComparison.OrdinalIgnoreCase)
        || String.Equals(name, "netstandard", StringComparison.OrdinalIgnoreCase)
        || String.Equals(name, "System.Private.CoreLib", StringComparison.OrdinalIgnoreCase)

// --------------------------------------------------------------------
// Utilities: type names
// --------------------------------------------------------------------

/// Global State. All namespace splits ever seen
// ++GLOBAL MUTABLE STATE (concurrency-safe)
let memoizeNamespaceTable = ConcurrentDictionary<string, string list>()

//  ++GLOBAL MUTABLE STATE (concurrency-safe)
let memoizeNamespaceRightTable =
    ConcurrentDictionary<string, string option * string>()

// ++GLOBAL MUTABLE STATE (concurrency-safe)
let memoizeNamespacePartTable = ConcurrentDictionary<string, string>()

let splitNameAt (nm: string) idx =
    if idx < 0 then
        failwith "splitNameAt: idx < 0"

    let last = nm.Length - 1

    if idx > last then
        failwith "splitNameAt: idx > last"

    nm.Substring(0, idx), (if idx < last then nm.Substring(idx + 1, last - idx) else "")

let rec splitNamespaceAux (nm: string) =
    match nm.IndexOf '.' with
    | -1 -> [ nm ]
    | idx ->
        let s1, s2 = splitNameAt nm idx
        let s1 = memoizeNamespacePartTable.GetOrAdd(s1, s1)
        s1 :: splitNamespaceAux s2

// Cache this as a delegate.
let splitNamespaceAuxDelegate = Func<string, string list> splitNamespaceAux

let splitNamespace nm =
    memoizeNamespaceTable.GetOrAdd(nm, splitNamespaceAuxDelegate)

// ++GLOBAL MUTABLE STATE (concurrency-safe)
let memoizeNamespaceArrayTable = ConcurrentDictionary<string, string[]>()

// Cache this as a delegate.
let splitNamespaceToArrayDelegate =
    Func<string, string array>(splitNamespace >> Array.ofList)

let splitNamespaceToArray nm =
    memoizeNamespaceArrayTable.GetOrAdd(nm, splitNamespaceToArrayDelegate)

let splitILTypeName (nm: string) =
    match nm.LastIndexOf '.' with
    | -1 -> [], nm
    | idx ->
        let s1, s2 = splitNameAt nm idx
        splitNamespace s1, s2

// Duplicate of comment in import.fs:
//   The type names that flow to the point include the "mangled" type names used for static parameters for provided types.
//   For example,
//       Foo.Bar,"1.0"
//   This is because the ImportSystemType code goes via Abstract IL type references. Ultimately this probably isn't
//   the best way to do things.
let splitILTypeNameWithPossibleStaticArguments (nm: string) =
    let nm, suffix =
        match nm.IndexOf ',' with
        | -1 -> nm, None
        | idx -> let s1, s2 = splitNameAt nm idx in s1, Some s2

    let nsp, nm =
        match nm.LastIndexOf '.' with
        | -1 -> [||], nm
        | idx ->
            let s1, s2 = splitNameAt nm idx
            splitNamespaceToArray s1, s2

    nsp,
    (match suffix with
     | None -> nm
     | Some s -> nm + "," + s)

(*
splitILTypeNameWithPossibleStaticArguments "Foo" = ([| |], "Foo")
splitILTypeNameWithPossibleStaticArguments "Foo.Bar" = ([| "Foo" |], "Bar")
splitILTypeNameWithPossibleStaticArguments "Foo.Bar,3" = ([| "Foo" |], "Bar, 3")
splitILTypeNameWithPossibleStaticArguments "Foo.Bar," = ([| "Foo" |], "Bar,")
splitILTypeNameWithPossibleStaticArguments "Foo.Bar,\"1.0\"" = ([| "Foo" |], "Bar,\"1.0\"")
splitILTypeNameWithPossibleStaticArguments "Foo.Bar.Bar,\"1.0\"" = ([| "Foo"; "Bar" |], "Bar,\"1.0\"")
*)

let splitTypeNameRightAux (nm: string) =
    let idx = nm.LastIndexOf '.'

    if idx = -1 then
        None, nm
    else
        let s1, s2 = splitNameAt nm idx
        Some s1, s2

// Cache this as a delegate.
let splitTypeNameRightAuxDelegate =
    Func<string, string option * string> splitTypeNameRightAux

let splitTypeNameRight nm =
    memoizeNamespaceRightTable.GetOrAdd(nm, splitTypeNameRightAuxDelegate)

// --------------------------------------------------------------------
// Ordered lists with a lookup table
// --------------------------------------------------------------------

/// This is used to store event, property and field maps.
type LazyOrderedMultiMap<'Key, 'Data when 'Key: equality and 'Key: not null>(keyf: 'Data -> 'Key, lazyItems: InterruptibleLazy<'Data list>)
    =

    let quickMap =
        lazyItems
        |> lazyMap (fun entries ->
            let t = Dictionary<_, _>(entries.Length, HashIdentity.Structural)

            for y in entries do
                let key = keyf y

                let v =
                    match t.TryGetValue key with
                    | true, v -> v
                    | _ -> []

                t[key] <- y :: v

            t)

    member _.Entries() = lazyItems.Force()

    member _.Add y =
        new LazyOrderedMultiMap<'Key, 'Data>(keyf, lazyItems |> lazyMap (fun x -> y :: x))

    member _.Filter f =
        new LazyOrderedMultiMap<'Key, 'Data>(keyf, lazyItems |> lazyMap (List.filter f))

    member _.Item
        with get x =
            match quickMap.Force().TryGetValue x with
            | true, v -> v
            | _ -> []

    override _.ToString() = "<table>"

//---------------------------------------------------------------------
// SHA1 hash-signing algorithm. Used to get the public key token from
// the public key.
//---------------------------------------------------------------------

let b0 n = (n &&& 0xFF)
let b1 n = ((n >>> 8) &&& 0xFF)
let b2 n = ((n >>> 16) &&& 0xFF)
let b3 n = ((n >>> 24) &&& 0xFF)

module SHA1 =

    let inline (>>>&) (x: int) (y: int) = int32 (uint32 x >>> y)

    let f (t, b, c, d) =
        if t < 20 then (b &&& c) ||| ((~~~b) &&& d)
        elif t < 40 then b ^^^ c ^^^ d
        elif t < 60 then (b &&& c) ||| (b &&& d) ||| (c &&& d)
        else b ^^^ c ^^^ d

    [<Literal>]
    let k0to19 = 0x5A827999

    [<Literal>]
    let k20to39 = 0x6ED9EBA1

    [<Literal>]
    let k40to59 = 0x8F1BBCDC

    [<Literal>]
    let k60to79 = 0xCA62C1D6

    let k t =
        if t < 20 then k0to19
        elif t < 40 then k20to39
        elif t < 60 then k40to59
        else k60to79

    type SHAStream =
        {
            stream: byte[]
            mutable pos: int
            mutable eof: bool
        }

    let rotLeft32 x n = (x <<< n) ||| (x >>>& (32 - n))

    // padding and length (in bits!) recorded at end
    let shaAfterEof sha =
        let n = sha.pos
        let len = sha.stream.Length

        if n = len then
            0x80
        else
            let padded_len = (((len + 9 + 63) / 64) * 64) - 8

            if n < padded_len - 8 then
                0x0
            elif (n &&& 63) = 56 then
                int32 ((int64 len * int64 8) >>> 56) &&& 0xff
            elif (n &&& 63) = 57 then
                int32 ((int64 len * int64 8) >>> 48) &&& 0xff
            elif (n &&& 63) = 58 then
                int32 ((int64 len * int64 8) >>> 40) &&& 0xff
            elif (n &&& 63) = 59 then
                int32 ((int64 len * int64 8) >>> 32) &&& 0xff
            elif (n &&& 63) = 60 then
                int32 ((int64 len * int64 8) >>> 24) &&& 0xff
            elif (n &&& 63) = 61 then
                int32 ((int64 len * int64 8) >>> 16) &&& 0xff
            elif (n &&& 63) = 62 then
                int32 ((int64 len * int64 8) >>> 8) &&& 0xff
            elif (n &&& 63) = 63 then
                (sha.eof <- true
                 int32 (int64 len * int64 8) &&& 0xff)
            else
                0x0

    let shaRead8 sha =
        let s = sha.stream

        let b =
            if sha.pos >= s.Length then
                shaAfterEof sha
            else
                int32 s[sha.pos]

        sha.pos <- sha.pos + 1
        b

    let shaRead32 sha =
        let b0 = shaRead8 sha
        let b1 = shaRead8 sha
        let b2 = shaRead8 sha
        let b3 = shaRead8 sha
        let res = (b0 <<< 24) ||| (b1 <<< 16) ||| (b2 <<< 8) ||| b3
        res

    let sha1Hash sha =
        let mutable h0 = 0x67452301
        let mutable h1 = 0xEFCDAB89
        let mutable h2 = 0x98BADCFE
        let mutable h3 = 0x10325476
        let mutable h4 = 0xC3D2E1F0
        let mutable a = 0
        let mutable b = 0
        let mutable c = 0
        let mutable d = 0
        let mutable e = 0
        let w = Array.create 80 0x00

        while (not sha.eof) do
            for i = 0 to 15 do
                w[i] <- shaRead32 sha

            for t = 16 to 79 do
                w[t] <- rotLeft32 (w[t - 3] ^^^ w[t - 8] ^^^ w[t - 14] ^^^ w[t - 16]) 1

            a <- h0
            b <- h1
            c <- h2
            d <- h3
            e <- h4

            for t = 0 to 79 do
                let temp = (rotLeft32 a 5) + f (t, b, c, d) + e + w[t] + k t
                e <- d
                d <- c
                c <- rotLeft32 b 30
                b <- a
                a <- temp

            h0 <- h0 + a
            h1 <- h1 + b
            h2 <- h2 + c
            h3 <- h3 + d
            h4 <- h4 + e

        h0, h1, h2, h3, h4

    let sha1HashBytes s =
        let _h0, _h1, _h2, h3, h4 = sha1Hash { stream = s; pos = 0; eof = false } // the result of the SHA algorithm is stored in registers 3 and 4
        Array.map byte [| b0 h4; b1 h4; b2 h4; b3 h4; b0 h3; b1 h3; b2 h3; b3 h3 |]

    let sha1HashInt64 s =
        let _h0, _h1, _h2, h3, h4 = sha1Hash { stream = s; pos = 0; eof = false } // the result of the SHA algorithm is stored in registers 3 and 4
        (int64 h3 <<< 32) ||| int64 h4

let sha1HashBytes s = SHA1.sha1HashBytes s
let sha1HashInt64 s = SHA1.sha1HashInt64 s

// --------------------------------------------------------------------
//
// --------------------------------------------------------------------

[<Struct>]
type ILVersionInfo =

    val Major: uint16
    val Minor: uint16
    val Build: uint16
    val Revision: uint16

    new(major, minor, build, revision) =
        {
            Major = major
            Minor = minor
            Build = build
            Revision = revision
        }

    /// For debugging
    override x.ToString() =
        sprintf "ILVersionInfo: %u %u %u %u" x.Major x.Minor x.Build x.Revision

type Locale = string

[<StructuralEquality; StructuralComparison>]
type PublicKey =

    | PublicKey of byte[]

    | PublicKeyToken of byte[]

    member x.IsKey =
        match x with
        | PublicKey _ -> true
        | _ -> false

    member x.IsKeyToken =
        match x with
        | PublicKeyToken _ -> true
        | _ -> false

    member x.Key =
        match x with
        | PublicKey b -> b
        | _ -> invalidOp "not a key"

    member x.KeyToken =
        match x with
        | PublicKeyToken b -> b
        | _ -> invalidOp "not a key token"

    member x.ToToken() =
        match x with
        | PublicKey bytes -> SHA1.sha1HashBytes bytes
        | PublicKeyToken token -> token

    static member KeyAsToken key =
        PublicKeyToken(PublicKey(key).ToToken())

[<StructuralEquality; StructuralComparison>]
type AssemblyRefData =
    {
        assemRefName: string
        assemRefHash: byte[] option
        assemRefPublicKeyInfo: PublicKey option
        assemRefRetargetable: bool
        assemRefVersion: ILVersionInfo option
        assemRefLocale: Locale option
    }

    override x.ToString() = x.assemRefName

/// Global state: table of all assembly references keyed by AssemblyRefData.
let AssemblyRefUniqueStampGenerator = UniqueStampGenerator<AssemblyRefData>()

[<Sealed>]
type ILAssemblyRef(data) =
    let pkToken key =
        match key with
        | Some(PublicKey bytes) -> Some(PublicKey(SHA1.sha1HashBytes bytes))
        | Some(PublicKeyToken token) -> Some(PublicKey token)
        | None -> None

    let uniqueStamp =
        AssemblyRefUniqueStampGenerator.Encode
            { data with
                assemRefPublicKeyInfo = pkToken data.assemRefPublicKeyInfo
            }

    let uniqueIgnoringVersionStamp =
        AssemblyRefUniqueStampGenerator.Encode
            { data with
                assemRefVersion = None
                assemRefPublicKeyInfo = pkToken data.assemRefPublicKeyInfo
            }

    member x.Name = data.assemRefName

    member x.Hash = data.assemRefHash

    member x.PublicKey = data.assemRefPublicKeyInfo

    member x.Retargetable = data.assemRefRetargetable

    member x.Version = data.assemRefVersion

    member x.Locale = data.assemRefLocale

    member x.UniqueStamp = uniqueStamp

    member x.UniqueIgnoringVersionStamp = uniqueIgnoringVersionStamp

    member x.EqualsIgnoringVersion(aref: ILAssemblyRef) =
        aref.UniqueIgnoringVersionStamp = uniqueIgnoringVersionStamp

    override x.GetHashCode() = uniqueStamp

    override x.Equals yobj =
        ((!!yobj :?> ILAssemblyRef).UniqueStamp = uniqueStamp)

    interface IComparable with
        override x.CompareTo yobj =
            compare (!!yobj :?> ILAssemblyRef).UniqueStamp uniqueStamp

    static member Create(name, hash, publicKey, retargetable, version, locale) =
        ILAssemblyRef
            {
                assemRefName = name
                assemRefHash = hash
                assemRefPublicKeyInfo = publicKey
                assemRefRetargetable = retargetable
                assemRefVersion = version
                assemRefLocale = locale
            }

#if !FABLE_COMPILER
    static member FromAssemblyName(aname: AssemblyName) =

        let locale = None

        let publicKey =
            match aname.GetPublicKey() with
            | null
            | [||] ->
                match aname.GetPublicKeyToken() with
                | null
                | [||] -> None
                | bytes -> Some(PublicKeyToken bytes)
            | bytes -> Some(PublicKey bytes)

        let version =
            match aname.Version with
            | null -> None
            | v -> Some(ILVersionInfo(uint16 v.Major, uint16 v.Minor, uint16 v.Build, uint16 v.Revision))

        let retargetable = aname.Flags = AssemblyNameFlags.Retargetable

        let name =
            match aname.Name with
            | null -> aname.FullName
            | name -> name

        ILAssemblyRef.Create(name, None, publicKey, retargetable, version, locale)
#endif //!FABLE_COMPILER

    member aref.QualifiedName =
        let b = StringBuilder(100)
        let add (s: string) = b.Append s |> ignore
        let addC (s: char) = b.Append s |> ignore
        add aref.Name

        match aref.Version with
        | None -> ()
        | Some version ->
            add ", Version="
            add (string (int version.Major))
            add "."
            add (string (int version.Minor))
            add "."
            add (string (int version.Build))
            add "."
            add (string (int version.Revision))
            add ", Culture="

            match aref.Locale with
            | None -> add "neutral"
            | Some b -> add b

            add ", PublicKeyToken="

            match aref.PublicKey with
            | None -> add "null"
            | Some pki ->
                let pkt = pki.ToToken()

                let convDigit digit =
                    let digitc =
                        if digit < 10 then
                            Convert.ToInt32 '0' + digit
                        else
                            Convert.ToInt32 'a' + (digit - 10)

                    Convert.ToChar digitc

                for i = 0 to pkt.Length - 1 do
                    let v = pkt[i]
                    addC (convDigit (int32 v / 16))
                    addC (convDigit (int32 v % 16))
            // retargetable can be true only for system assemblies that definitely have Version
            if aref.Retargetable then
                add ", Retargetable=Yes"

        b.ToString()

[<StructuralEquality; StructuralComparison>]
type ILModuleRef =
    {
        name: string
        hasMetadata: bool
        hash: byte[] option
    }

    static member Create(name, hasMetadata, hash) =
        {
            name = name
            hasMetadata = hasMetadata
            hash = hash
        }

    member x.Name = x.name

    member x.HasMetadata = x.hasMetadata

    member x.Hash = x.hash

    override x.ToString() = x.Name

[<StructuralEquality; StructuralComparison>]
[<RequireQualifiedAccess>]
type ILScopeRef =
    | Local
    | Module of ILModuleRef
    | Assembly of ILAssemblyRef
    | PrimaryAssembly

    member x.IsLocalRef =
        match x with
        | ILScopeRef.Local -> true
        | _ -> false

    member x.QualifiedName =
        match x with
        | ILScopeRef.Local -> ""
        | ILScopeRef.Module mref -> "module " + mref.Name
        | ILScopeRef.Assembly aref -> aref.QualifiedName
        | ILScopeRef.PrimaryAssembly -> ""

type ILArrayBound = int32 option

type ILArrayBounds = ILArrayBound * ILArrayBound

[<StructuralEquality; StructuralComparison>]
type ILArrayShape =

    | ILArrayShape of ILArrayBounds list (* lobound/size pairs *)

    member x.Rank = (let (ILArrayShape l) = x in l.Length)

    static member SingleDimensional = ILArrayShapeStatics.SingleDimensional

    static member FromRank n =
        if n = 1 then
            ILArrayShape.SingleDimensional
        else
            ILArrayShape(List.replicate n (Some 0, None))

and ILArrayShapeStatics() =

    static let singleDimensional = ILArrayShape [ (Some 0, None) ]

    static member SingleDimensional = singleDimensional

/// Calling conventions. These are used in method pointer types.
[<StructuralEquality; StructuralComparison; RequireQualifiedAccess>]
type ILArgConvention =
    | Default
    | CDecl
    | StdCall
    | ThisCall
    | FastCall
    | VarArg

[<StructuralEquality; StructuralComparison; RequireQualifiedAccess>]
type ILThisConvention =
    | Instance
    | InstanceExplicit
    | Static

[<StructuralEquality; StructuralComparison>]
type ILCallingConv =

    | Callconv of ILThisConvention * ILArgConvention

    member x.ThisConv = let (Callconv(a, _b)) = x in a

    member x.BasicConv = let (Callconv(_a, b)) = x in b

    member x.IsInstance =
        match x.ThisConv with
        | ILThisConvention.Instance -> true
        | _ -> false

    member x.IsInstanceExplicit =
        match x.ThisConv with
        | ILThisConvention.InstanceExplicit -> true
        | _ -> false

    member x.IsStatic =
        match x.ThisConv with
        | ILThisConvention.Static -> true
        | _ -> false

    static member Instance = ILCallingConvStatics.Instance

    static member Static = ILCallingConvStatics.Static

    override x.ToString() =
        if x.IsStatic then "static" else "instance"

/// Static storage to amortize the allocation of <c>ILCallingConv.Instance</c> and <c>ILCallingConv.Static</c>.
and ILCallingConvStatics() =

    static let instanceCallConv = Callconv(ILThisConvention.Instance, ILArgConvention.Default)

    static let staticCallConv = Callconv(ILThisConvention.Static, ILArgConvention.Default)

    static member Instance = instanceCallConv

    static member Static = staticCallConv

type ILBoxity =
    | AsObject
    | AsValue

// IL type references have a pre-computed hash code to enable quick lookup tables during binary generation.
[<CustomEquality; CustomComparison; StructuredFormatDisplay("{DebugText}")>]
type ILTypeRef =
    {
        trefScope: ILScopeRef
        trefEnclosing: string list
        trefName: string
        hashCode: int
        mutable asBoxedType: ILType
    }

    static member ComputeHash(scope, enclosing, name) =
        hash scope * 17 ^^^ (hash enclosing * 101 <<< 1) ^^^ (hash name * 47 <<< 2)

    static member Create(scope, enclosing, name) =
        let hashCode = ILTypeRef.ComputeHash(scope, enclosing, name)

        {
            trefScope = scope
            trefEnclosing = enclosing
            trefName = name
            hashCode = hashCode
            asBoxedType = Unchecked.defaultof<_>
        }

    member x.Scope = x.trefScope

    member x.Enclosing = x.trefEnclosing

    member x.Name = x.trefName

    member x.ApproxId = x.hashCode

    member x.AsBoxedType(tspec: ILTypeSpec) =
        if isNil tspec.tspecInst then
            let v = x.asBoxedType

            match box v with
            | null ->
                let r = ILType.Boxed tspec
                x.asBoxedType <- r
                r
            | _ -> v
        else
            ILType.Boxed tspec

    override x.GetHashCode() = x.hashCode

    override x.Equals yobj =
        let y = (!!yobj :?> ILTypeRef)

        (x.ApproxId = y.ApproxId)
        && (x.Scope = y.Scope)
        && (x.Name = y.Name)
        && (x.Enclosing = y.Enclosing)

    member x.EqualsWithPrimaryScopeRef(primaryScopeRef: ILScopeRef, yobj: obj) =
        let y = (yobj :?> ILTypeRef)

        let isPrimary (v: ILTypeRef) =
            match v.Scope with
            | ILScopeRef.PrimaryAssembly -> true
            | _ -> false

        // Since we can remap the scope, we need to recompute hash ... this is not an expensive operation
        let isPrimaryX = isPrimary x
        let isPrimaryY = isPrimary y

        let xApproxId =
            if isPrimaryX && not isPrimaryY then
                ILTypeRef.ComputeHash(primaryScopeRef, x.Enclosing, x.Name)
            else
                x.ApproxId

        let yApproxId =
            if isPrimaryY && not isPrimaryX then
                ILTypeRef.ComputeHash(primaryScopeRef, y.Enclosing, y.Name)
            else
                y.ApproxId

        let xScope = if isPrimaryX then primaryScopeRef else x.Scope

        let yScope = if isPrimaryY then primaryScopeRef else y.Scope

        (xApproxId = yApproxId)
        && (xScope = yScope)
        && (x.Name = y.Name)
        && (x.Enclosing = y.Enclosing)

    interface IComparable with

        override x.CompareTo yobj =
            let y = (!!yobj :?> ILTypeRef)
            let c = compare x.ApproxId y.ApproxId

            if c <> 0 then
                c
            else
                let c = compare x.Scope y.Scope

                if c <> 0 then
                    c
                else
                    let c = compare x.Name y.Name

                    if c <> 0 then c else compare x.Enclosing y.Enclosing

    member tref.FullName = String.concat "." (tref.Enclosing @ [ tref.Name ])

    member tref.BasicQualifiedName =
        (String.concat "+" (tref.Enclosing @ [ tref.Name ])).Replace(",", @"\,")

    member tref.AddQualifiedNameExtension basic =
        let sco = tref.Scope.QualifiedName

        if String.IsNullOrEmpty(sco) then
            basic
        else
            String.concat ", " [ basic; sco ]

    member tref.QualifiedName = tref.AddQualifiedNameExtension tref.BasicQualifiedName

    /// For debugging
    [<DebuggerBrowsable(DebuggerBrowsableState.Never)>]
    member x.DebugText = x.ToString()

    /// For debugging
    override x.ToString() : string = x.FullName

and [<StructuralEquality; StructuralComparison; StructuredFormatDisplay("{DebugText}")>] ILTypeSpec =
    {
        tspecTypeRef: ILTypeRef
        /// The type instantiation if the type is generic.
        tspecInst: ILGenericArgs
    }

    member x.TypeRef = x.tspecTypeRef

    member x.Scope = x.TypeRef.Scope

    member x.Enclosing = x.TypeRef.Enclosing

    member x.Name = x.TypeRef.Name

    member x.GenericArgs = x.tspecInst

    static member Create(typeRef, instantiation) =
        {
            tspecTypeRef = typeRef
            tspecInst = instantiation
        }

    member x.BasicQualifiedName =
        let tc = x.TypeRef.BasicQualifiedName

        if isNil x.GenericArgs then
            tc
        else
            tc
            + "["
            + String.concat "," (x.GenericArgs |> List.map (fun arg -> "[" + arg.QualifiedName + "]"))
            + "]"

    member x.AddQualifiedNameExtension basic =
        x.TypeRef.AddQualifiedNameExtension basic

    member x.FullName = x.TypeRef.FullName

    /// For debugging
    [<DebuggerBrowsable(DebuggerBrowsableState.Never)>]
    member x.DebugText = x.ToString()

    member x.EqualsWithPrimaryScopeRef(primaryScopeRef: ILScopeRef, yobj: obj) =
        let y = (yobj :?> ILTypeSpec)

        x.tspecTypeRef.EqualsWithPrimaryScopeRef(primaryScopeRef, y.TypeRef)
        && (x.GenericArgs = y.GenericArgs)

    override x.ToString() =
        x.TypeRef.FullName + if isNil x.GenericArgs then "" else "<...>"

and [<RequireQualifiedAccess; StructuralEquality; StructuralComparison; StructuredFormatDisplay("{DebugText}")>] ILType =
    | Void
    | Array of ILArrayShape * ILType
    | Value of ILTypeSpec
    | Boxed of ILTypeSpec
    | Ptr of ILType
    | Byref of ILType
    | FunctionPointer of ILCallingSignature
    | TypeVar of uint16
    | Modified of bool * ILTypeRef * ILType

    member x.BasicQualifiedName =
        match x with
        | ILType.TypeVar n -> "!" + string n
        | ILType.Modified(_, _ty1, ty2) -> ty2.BasicQualifiedName
        | ILType.Array(ILArrayShape s, ty) -> ty.BasicQualifiedName + "[" + String(',', s.Length - 1) + "]"
        | ILType.Value tr
        | ILType.Boxed tr -> tr.BasicQualifiedName
        | ILType.Void -> "void"
        | ILType.Ptr _ty -> failwith "unexpected pointer type"
        | ILType.Byref _ty -> failwith "unexpected byref type"
        | ILType.FunctionPointer _mref -> failwith "unexpected function pointer type"

    member x.AddQualifiedNameExtension basic =
        match x with
        | ILType.TypeVar _n -> basic
        | ILType.Modified(_, _ty1, ty2) -> ty2.AddQualifiedNameExtension basic
        | ILType.Array(ILArrayShape(_s), ty) -> ty.AddQualifiedNameExtension basic
        | ILType.Value tr
        | ILType.Boxed tr -> tr.AddQualifiedNameExtension basic
        | ILType.Void -> failwith "void"
        | ILType.Ptr _ty -> failwith "unexpected pointer type"
        | ILType.Byref _ty -> failwith "unexpected byref type"
        | ILType.FunctionPointer _mref -> failwith "unexpected function pointer type"

    member x.QualifiedName = x.AddQualifiedNameExtension(x.BasicQualifiedName)

    member x.TypeSpec =
        match x with
        | ILType.Boxed tr
        | ILType.Value tr -> tr
        | _ -> invalidOp "not a nominal type"

    member x.Boxity =
        match x with
        | ILType.Boxed _ -> AsObject
        | ILType.Value _ -> AsValue
        | _ -> invalidOp "not a nominal type"

    member x.TypeRef =
        match x with
        | ILType.Boxed tspec
        | ILType.Value tspec -> tspec.TypeRef
        | _ -> invalidOp "not a nominal type"

    member x.IsNominal =
        match x with
        | ILType.Boxed _
        | ILType.Value _ -> true
        | _ -> false

    member x.GenericArgs =
        match x with
        | ILType.Boxed tspec
        | ILType.Value tspec -> tspec.GenericArgs
        | _ -> []

    member x.IsTyvar =
        match x with
        | ILType.TypeVar _ -> true
        | _ -> false

    /// For debugging
    [<DebuggerBrowsable(DebuggerBrowsableState.Never)>]
    member x.DebugText = x.ToString()

    override x.ToString() = x.QualifiedName

and [<StructuralEquality; StructuralComparison>] ILCallingSignature =
    {
        CallingConv: ILCallingConv
        ArgTypes: ILTypes
        ReturnType: ILType
    }

and ILGenericArgs = ILType list

and ILTypes = ILType list

let mkILCallSig (cc, args, ret) =
    {
        ArgTypes = args
        CallingConv = cc
        ReturnType = ret
    }

let mkILBoxedType (tspec: ILTypeSpec) = tspec.TypeRef.AsBoxedType tspec

[<StructuralEquality; StructuralComparison; StructuredFormatDisplay("{DebugText}")>]
type ILMethodRef =
    {
        mrefParent: ILTypeRef
        mrefCallconv: ILCallingConv
        mrefGenericArity: int
        mrefName: string
        mrefArgs: ILTypes
        mrefReturn: ILType
    }

    member x.DeclaringTypeRef = x.mrefParent

    member x.CallingConv = x.mrefCallconv

    member x.Name = x.mrefName

    member x.GenericArity = x.mrefGenericArity

    member x.ArgCount = List.length x.mrefArgs

    member x.ArgTypes = x.mrefArgs

    member x.ReturnType = x.mrefReturn

    member x.GetCallingSignature() =
        mkILCallSig (x.CallingConv, x.ArgTypes, x.ReturnType)

    static member Create(enclosingTypeRef, callingConv, name, genericArity, argTypes, returnType) =
        {
            mrefParent = enclosingTypeRef
            mrefCallconv = callingConv
            mrefName = name
            mrefGenericArity = genericArity
            mrefArgs = argTypes
            mrefReturn = returnType
        }

    /// For debugging
    [<DebuggerBrowsable(DebuggerBrowsableState.Never)>]
    member x.DebugText = x.ToString()

    member x.FullName = x.DeclaringTypeRef.FullName + "::" + x.Name + "(...)"

    override x.ToString() = x.FullName

[<StructuralEquality; StructuralComparison; StructuredFormatDisplay("{DebugText}")>]
type ILFieldRef =
    {
        DeclaringTypeRef: ILTypeRef
        Name: string
        Type: ILType
    }

    /// For debugging
    [<DebuggerBrowsable(DebuggerBrowsableState.Never)>]
    member x.DebugText = x.ToString()

    override x.ToString() =
        x.DeclaringTypeRef.FullName + "::" + x.Name

[<StructuralEquality; StructuralComparison; StructuredFormatDisplay("{DebugText}")>]
type ILMethodSpec =
    {
        mspecMethodRef: ILMethodRef

        mspecDeclaringType: ILType

        mspecMethodInst: ILGenericArgs
    }

    static member Create(a, b, c) =
        {
            mspecDeclaringType = a
            mspecMethodRef = b
            mspecMethodInst = c
        }

    member x.MethodRef = x.mspecMethodRef

    member x.DeclaringType = x.mspecDeclaringType

    member x.GenericArgs = x.mspecMethodInst

    member x.Name = x.MethodRef.Name

    member x.CallingConv = x.MethodRef.CallingConv

    member x.GenericArity = x.MethodRef.GenericArity

    member x.FormalArgTypes = x.MethodRef.ArgTypes

    member x.FormalReturnType = x.MethodRef.ReturnType

    /// For debugging
    [<DebuggerBrowsable(DebuggerBrowsableState.Never)>]
    member x.DebugText = x.ToString()

    override x.ToString() = x.MethodRef.FullName + "(...)"

[<StructuralEquality; StructuralComparison; StructuredFormatDisplay("{DebugText}")>]
type ILFieldSpec =
    {
        FieldRef: ILFieldRef
        DeclaringType: ILType
    }

    member x.FormalType = x.FieldRef.Type

    member x.Name = x.FieldRef.Name

    member x.DeclaringTypeRef = x.FieldRef.DeclaringTypeRef

    /// For debugging
    [<DebuggerBrowsable(DebuggerBrowsableState.Never)>]
    member x.DebugText = x.ToString()

    override x.ToString() = x.FieldRef.ToString()

// --------------------------------------------------------------------
// Debug info.
// --------------------------------------------------------------------

type ILGuid = byte[]

type ILPlatform =
    | X86
    | AMD64
    | IA64
    | ARM
    | ARM64

type ILSourceDocument =
    {
        sourceLanguage: ILGuid option
        sourceVendor: ILGuid option
        sourceDocType: ILGuid option
        sourceFile: string
    }

    static member Create(language, vendor, documentType, file) =
        {
            sourceLanguage = language
            sourceVendor = vendor
            sourceDocType = documentType
            sourceFile = file
        }

    member x.Language = x.sourceLanguage

    member x.Vendor = x.sourceVendor

    member x.DocumentType = x.sourceDocType

    member x.File = x.sourceFile

    override x.ToString() = x.File

[<StructuralEquality; StructuralComparison; StructuredFormatDisplay("{DebugText}")>]
type ILDebugPoint =
    {
        sourceDocument: ILSourceDocument
        sourceLine: int
        sourceColumn: int
        sourceEndLine: int
        sourceEndColumn: int
    }

    static member Create(document, line, column, endLine, endColumn) =
        {
            sourceDocument = document
            sourceLine = line
            sourceColumn = column
            sourceEndLine = endLine
            sourceEndColumn = endColumn
        }

    member x.Document = x.sourceDocument

    member x.Line = x.sourceLine

    member x.Column = x.sourceColumn

    member x.EndLine = x.sourceEndLine

    member x.EndColumn = x.sourceEndColumn

    /// For debugging
    [<DebuggerBrowsable(DebuggerBrowsableState.Never)>]
    member x.DebugText = x.ToString()

    override x.ToString() =
        sprintf "(%d, %d)-(%d, %d)" x.Line x.Column x.EndLine x.EndColumn

type ILAttribElem =
    | String of string option
    | Bool of bool
    | Char of char
    | SByte of int8
    | Int16 of int16
    | Int32 of int32
    | Int64 of int64
    | Byte of uint8
    | UInt16 of uint16
    | UInt32 of uint32
    | UInt64 of uint64
    | Single of single
    | Double of double
    | Null
    | Type of ILType option
    | TypeRef of ILTypeRef option
    | Array of ILType * ILAttribElem list

type ILAttributeNamedArg = string * ILType * bool * ILAttribElem

[<RequireQualifiedAccess; StructuralEquality; StructuralComparison; StructuredFormatDisplay("{DebugText}")>]
type ILAttribute =
    | Encoded of method: ILMethodSpec * data: byte[] * elements: ILAttribElem list
    | Decoded of method: ILMethodSpec * fixedArgs: ILAttribElem list * namedArgs: ILAttributeNamedArg list

    member x.Method =
        match x with
        | Encoded(method, _, _)
        | Decoded(method, _, _) -> method

    member x.Elements =
        match x with
        | Encoded(_, _, elements) -> elements
        | Decoded(_, fixedArgs, namedArgs) -> fixedArgs @ (namedArgs |> List.map (fun (_, _, _, e) -> e))

    member x.WithMethod(method: ILMethodSpec) =
        match x with
        | Encoded(_, data, elements) -> Encoded(method, data, elements)
        | Decoded(_, fixedArgs, namedArgs) -> Decoded(method, fixedArgs, namedArgs)

    /// For debugging
    [<DebuggerBrowsable(DebuggerBrowsableState.Never)>]
    member x.DebugText = x.ToString()

    override x.ToString() = x.Method.MethodRef.FullName

[<NoEquality; NoComparison; Struct>]
type ILAttributes(array: ILAttribute[]) =
    member _.AsArray() = array

    member _.AsList() = array |> Array.toList

    static member val internal Empty = ILAttributes([||])

[<NoEquality; NoComparison>]
type ILAttributesStored =

    /// Computed by ilread.fs based on metadata index
    | Reader of (int32 -> ILAttribute[])

    /// Already computed
    | Given of ILAttributes

    member x.GetCustomAttrs metadataIndex =
        match x with
        | Reader f -> ILAttributes(f metadataIndex)
        | Given attrs -> attrs

let emptyILCustomAttrs = ILAttributes [||]

let mkILCustomAttrsFromArray (attrs: ILAttribute[]) =
    if attrs.Length = 0 then
        emptyILCustomAttrs
    else
        ILAttributes attrs

let mkILCustomAttrs l =
    match l with
    | [] -> emptyILCustomAttrs
    | _ -> mkILCustomAttrsFromArray (List.toArray l)

let emptyILCustomAttrsStored = ILAttributesStored.Given emptyILCustomAttrs

let storeILCustomAttrs (attrs: ILAttributes) =
    if attrs.AsArray().Length = 0 then
        emptyILCustomAttrsStored
    else
        ILAttributesStored.Given attrs

let mkILCustomAttrsComputed f =
    ILAttributesStored.Reader(fun _ -> f ())

let mkILCustomAttrsReader f = ILAttributesStored.Reader f

type ILCodeLabel = int

// --------------------------------------------------------------------
// Instruction set.
// --------------------------------------------------------------------

type ILBasicType =
    | DT_R
    | DT_I1
    | DT_U1
    | DT_I2
    | DT_U2
    | DT_I4
    | DT_U4
    | DT_I8
    | DT_U8
    | DT_R4
    | DT_R8
    | DT_I
    | DT_U
    | DT_REF

[<StructuralEquality; StructuralComparison; RequireQualifiedAccess>]
type ILToken =
    | ILType of ILType
    | ILMethod of ILMethodSpec
    | ILField of ILFieldSpec

[<StructuralEquality; StructuralComparison; RequireQualifiedAccess>]
type ILConst =
    | I4 of int32
    | I8 of int64
    | R4 of single
    | R8 of double

type ILTailcall =
    | Tailcall
    | Normalcall

type ILAlignment =
    | Aligned
    | Unaligned1
    | Unaligned2
    | Unaligned4

type ILVolatility =
    | Volatile
    | Nonvolatile

type ILReadonly =
    | ReadonlyAddress
    | NormalAddress

type ILVarArgs = ILTypes option

[<StructuralEquality; StructuralComparison>]
type ILComparisonInstr =
    | BI_beq
    | BI_bge
    | BI_bge_un
    | BI_bgt
    | BI_bgt_un
    | BI_ble
    | BI_ble_un
    | BI_blt
    | BI_blt_un
    | BI_bne_un
    | BI_brfalse
    | BI_brtrue

[<StructuralEquality; NoComparison>]
type ILInstr =
    | AI_add
    | AI_add_ovf
    | AI_add_ovf_un
    | AI_and
    | AI_div
    | AI_div_un
    | AI_ceq
    | AI_cgt
    | AI_cgt_un
    | AI_clt
    | AI_clt_un
    | AI_conv of ILBasicType
    | AI_conv_ovf of ILBasicType
    | AI_conv_ovf_un of ILBasicType
    | AI_mul
    | AI_mul_ovf
    | AI_mul_ovf_un
    | AI_rem
    | AI_rem_un
    | AI_shl
    | AI_shr
    | AI_shr_un
    | AI_sub
    | AI_sub_ovf
    | AI_sub_ovf_un
    | AI_xor
    | AI_or
    | AI_neg
    | AI_not
    | AI_ldnull
    | AI_dup
    | AI_pop
    | AI_ckfinite
    | AI_nop
    | AI_ldc of ILBasicType * ILConst
    | I_ldarg of uint16
    | I_ldarga of uint16
    | I_ldind of ILAlignment * ILVolatility * ILBasicType
    | I_ldloc of uint16
    | I_ldloca of uint16
    | I_starg of uint16
    | I_stind of ILAlignment * ILVolatility * ILBasicType
    | I_stloc of uint16

    | I_br of ILCodeLabel
    | I_jmp of ILMethodSpec
    | I_brcmp of ILComparisonInstr * ILCodeLabel
    | I_switch of ILCodeLabel list
    | I_ret

    | I_call of ILTailcall * ILMethodSpec * ILVarArgs
    | I_callvirt of ILTailcall * ILMethodSpec * ILVarArgs
    | I_callconstraint of callvirt: bool * ILTailcall * ILType * ILMethodSpec * ILVarArgs
    | I_calli of ILTailcall * ILCallingSignature * ILVarArgs
    | I_ldftn of ILMethodSpec
    | I_newobj of ILMethodSpec * ILVarArgs

    | I_throw
    | I_endfinally
    | I_endfilter
    | I_leave of ILCodeLabel
    | I_rethrow

    | I_ldsfld of ILVolatility * ILFieldSpec
    | I_ldfld of ILAlignment * ILVolatility * ILFieldSpec
    | I_ldsflda of ILFieldSpec
    | I_ldflda of ILFieldSpec
    | I_stsfld of ILVolatility * ILFieldSpec
    | I_stfld of ILAlignment * ILVolatility * ILFieldSpec
    | I_ldstr of string
    | I_isinst of ILType
    | I_castclass of ILType
    | I_ldtoken of ILToken
    | I_ldvirtftn of ILMethodSpec

    | I_cpobj of ILType
    | I_initobj of ILType
    | I_ldobj of ILAlignment * ILVolatility * ILType
    | I_stobj of ILAlignment * ILVolatility * ILType
    | I_box of ILType
    | I_unbox of ILType
    | I_unbox_any of ILType
    | I_sizeof of ILType

    | I_ldelem of ILBasicType
    | I_stelem of ILBasicType
    | I_ldelema of ILReadonly * bool * ILArrayShape * ILType
    | I_ldelem_any of ILArrayShape * ILType
    | I_stelem_any of ILArrayShape * ILType
    | I_newarr of ILArrayShape * ILType
    | I_ldlen

    | I_mkrefany of ILType
    | I_refanytype
    | I_refanyval of ILType

    | I_break
    | I_seqpoint of ILDebugPoint

    | I_arglist

    | I_localloc
    | I_cpblk of ILAlignment * ILVolatility
    | I_initblk of ILAlignment * ILVolatility

    (* FOR EXTENSIONS, e.g. MS-ILX *)
    | EI_ilzero of ILType
    | EI_ldlen_multi of int32 * int32

[<RequireQualifiedAccess>]
type ILExceptionClause =
    | Finally of (ILCodeLabel * ILCodeLabel)
    | Fault of (ILCodeLabel * ILCodeLabel)
    | FilterCatch of filterRange: (ILCodeLabel * ILCodeLabel) * handlerRange: (ILCodeLabel * ILCodeLabel)
    | TypeCatch of ILType * (ILCodeLabel * ILCodeLabel)

[<RequireQualifiedAccess; NoEquality; NoComparison>]
type ILExceptionSpec =
    {
        Range: ILCodeLabel * ILCodeLabel
        Clause: ILExceptionClause
    }

/// Indicates that a particular local variable has a particular source
/// language name within a given set of ranges. This does not effect local
/// variable numbering, which is global over the whole method.
[<RequireQualifiedAccess; NoEquality; NoComparison>]
type ILLocalDebugMapping = { LocalIndex: int; LocalName: string }

[<RequireQualifiedAccess; NoEquality; NoComparison>]
type ILLocalDebugInfo =
    {
        Range: ILCodeLabel * ILCodeLabel
        DebugMappings: ILLocalDebugMapping list
    }

    override x.ToString() =
        let firstLabel, secondLabel = x.Range
        sprintf "%i-%i" firstLabel secondLabel

[<RequireQualifiedAccess; NoEquality; NoComparison>]
type ILCode =
    {
        Labels: Dictionary<ILCodeLabel, int>
        Instrs: ILInstr[]
        Exceptions: ILExceptionSpec list
        Locals: ILLocalDebugInfo list
    }

    override x.ToString() = "<code>"

[<RequireQualifiedAccess; NoComparison; NoEquality>]
type ILLocal =
    {
        Type: ILType
        IsPinned: bool
        DebugInfo: (string * int * int) option
    }

    override x.ToString() = "<local>"

type ILLocals = ILLocal list

[<RequireQualifiedAccess; NoEquality; NoComparison>]
type ILDebugImport =
    | ImportType of targetType: ILType // * alias: string option
    | ImportNamespace of targetNamespace: string // * assembly: ILAssemblyRef option * alias: string option

//| ReferenceAlias of string
//| OpenXmlNamespace of prefix: string * xmlNamespace: string

type ILDebugImports =
    {
        Parent: ILDebugImports option
        Imports: ILDebugImport[]
    }

    override x.ToString() = "<imports>"

[<RequireQualifiedAccess; NoEquality; NoComparison>]
type ILMethodBody =
    {
        IsZeroInit: bool
        MaxStack: int32
        NoInlining: bool
        AggressiveInlining: bool
        Locals: ILLocals
        Code: ILCode
        DebugRange: ILDebugPoint option
        DebugImports: ILDebugImports option
    }

    override x.ToString() = "<method body>"

[<RequireQualifiedAccess>]
type ILMemberAccess =
    | Assembly
    | CompilerControlled
    | FamilyAndAssembly
    | FamilyOrAssembly
    | Family
    | Private
    | Public

[<RequireQualifiedAccess; StructuralEquality; StructuralComparison>]
type ILFieldInit =
    | String of string
    | Bool of bool
    | Char of uint16
    | Int8 of int8
    | Int16 of int16
    | Int32 of int32
    | Int64 of int64
    | UInt8 of uint8
    | UInt16 of uint16
    | UInt32 of uint32
    | UInt64 of uint64
    | Single of single
    | Double of double
    | Null

    member x.AsObject() =
        match x with
        | ILFieldInit.String s -> box s
        | ILFieldInit.Bool bool -> box bool
        | ILFieldInit.Char u16 -> box (char (int u16))
        | ILFieldInit.Int8 i8 -> box i8
        | ILFieldInit.Int16 i16 -> box i16
        | ILFieldInit.Int32 i32 -> box i32
        | ILFieldInit.Int64 i64 -> box i64
        | ILFieldInit.UInt8 u8 -> box u8
        | ILFieldInit.UInt16 u16 -> box u16
        | ILFieldInit.UInt32 u32 -> box u32
        | ILFieldInit.UInt64 u64 -> box u64
        | ILFieldInit.Single ieee32 -> box ieee32
        | ILFieldInit.Double ieee64 -> box ieee64
        | ILFieldInit.Null -> (null: objnull)

// --------------------------------------------------------------------
// Native Types, for marshalling to the native C interface.
// These are taken directly from the ILASM syntax, and don't really
// correspond yet to the CLI ECMA-335 Spec (Partition II, 7.4).
// --------------------------------------------------------------------

[<RequireQualifiedAccess; StructuralEquality; StructuralComparison>]
type ILNativeType =
    | Empty
    | Custom of ILGuid * nativeTypeName: string * custMarshallerName: string * cookieString: byte[]
    | FixedSysString of int32
    | FixedArray of int32
    | Currency
    | LPSTR
    | LPWSTR
    | LPTSTR
    | LPUTF8STR
    | ByValStr
    | TBSTR
    | LPSTRUCT
    | Struct
    | Void
    | Bool
    | Int8
    | Int16
    | Int32
    | Int64
    | Single
    | Double
    | Byte
    | UInt16
    | UInt32
    | UInt64
    | Array of
        ILNativeType option *
        (int32 * int32 option) option (* optional idx of parameter giving size plus optional additive i.e. num elems *)
    | Int
    | UInt
    | Method
    | AsAny
    | BSTR
    | IUnknown
    | IDispatch
    | Interface
    | Error
    | SafeArray of ILNativeVariant * string option
    | ANSIBSTR
    | VariantBool

and [<RequireQualifiedAccess; StructuralEquality; StructuralComparison>] ILNativeVariant =
    | Empty
    | Null
    | Variant
    | Currency
    | Decimal
    | Date
    | BSTR
    | LPSTR
    | LPWSTR
    | IUnknown
    | IDispatch
    | SafeArray
    | Error
    | HRESULT
    | CArray
    | UserDefined
    | Record
    | FileTime
    | Blob
    | Stream
    | Storage
    | StreamedObject
    | StoredObject
    | BlobObject
    | CF
    | CLSID
    | Void
    | Bool
    | Int8
    | Int16
    | Int32
    | Int64
    | Single
    | Double
    | UInt8
    | UInt16
    | UInt32
    | UInt64
    | PTR
    | Array of ILNativeVariant
    | Vector of ILNativeVariant
    | Byref of ILNativeVariant
    | Int
    | UInt

[<RequireQualifiedAccess; StructuralEquality; StructuralComparison>]
type ILSecurityAction =
    | Request
    | Demand
    | Assert
    | Deny
    | PermitOnly
    | LinkCheck
    | InheritCheck
    | ReqMin
    | ReqOpt
    | ReqRefuse
    | PreJitGrant
    | PreJitDeny
    | NonCasDemand
    | NonCasLinkDemand
    | NonCasInheritance
    | LinkDemandChoice
    | InheritanceDemandChoice
    | DemandChoice

[<RequireQualifiedAccess; StructuralEquality; StructuralComparison>]
type ILSecurityDecl = ILSecurityDecl of ILSecurityAction * byte[]

[<NoEquality; NoComparison; Struct>]
type ILSecurityDecls(array: ILSecurityDecl[]) =
    member x.AsArray() = array
    member x.AsList() = x.AsArray() |> Array.toList

[<NoEquality; NoComparison>]
type ILSecurityDeclsStored =

    /// Computed by ilread.fs based on metadata index
    | Reader of (int32 -> ILSecurityDecl[])

    /// Already computed
    | Given of ILSecurityDecls

    member x.GetSecurityDecls metadataIndex =
        match x with
        | Reader f -> ILSecurityDecls(f metadataIndex)
        | Given attrs -> attrs

let emptyILSecurityDecls = ILSecurityDecls [||]

let emptyILSecurityDeclsStored = ILSecurityDeclsStored.Given emptyILSecurityDecls

let mkILSecurityDecls l =
    match l with
    | [] -> emptyILSecurityDecls
    | _ -> ILSecurityDecls(Array.ofList l)

let storeILSecurityDecls (x: ILSecurityDecls) =
    if x.AsArray().Length = 0 then
        emptyILSecurityDeclsStored
    else
        ILSecurityDeclsStored.Given x

let mkILSecurityDeclsReader f = ILSecurityDeclsStored.Reader f

[<RequireQualifiedAccess>]
type PInvokeCharBestFit =
    | UseAssembly
    | Enabled
    | Disabled

[<RequireQualifiedAccess>]
type PInvokeThrowOnUnmappableChar =
    | UseAssembly
    | Enabled
    | Disabled

[<RequireQualifiedAccess>]
type PInvokeCallingConvention =
    | None
    | Cdecl
    | Stdcall
    | Thiscall
    | Fastcall
    | WinApi

[<RequireQualifiedAccess>]
type PInvokeCharEncoding =
    | None
    | Ansi
    | Unicode
    | Auto

[<RequireQualifiedAccess; NoComparison; NoEquality>]
type PInvokeMethod =
    {
        Where: ILModuleRef
        Name: string
        CallingConv: PInvokeCallingConvention
        CharEncoding: PInvokeCharEncoding
        NoMangle: bool
        LastError: bool
        ThrowOnUnmappableChar: PInvokeThrowOnUnmappableChar
        CharBestFit: PInvokeCharBestFit
    }

    override x.ToString() = x.Name

[<RequireQualifiedAccess; NoEquality; NoComparison>]
type ILParameter =
    {
        Name: string option
        Type: ILType
        Default: ILFieldInit option
        Marshal: ILNativeType option
        IsIn: bool
        IsOut: bool
        IsOptional: bool
        CustomAttrsStored: ILAttributesStored
        MetadataIndex: int32
    }

    member x.CustomAttrs = x.CustomAttrsStored.GetCustomAttrs x.MetadataIndex

    override x.ToString() =
        x.Name |> Option.defaultValue "<no name>"

type ILParameters = ILParameter list

[<RequireQualifiedAccess; NoEquality; NoComparison>]
type ILReturn =
    {
        Marshal: ILNativeType option
        Type: ILType
        CustomAttrsStored: ILAttributesStored
        MetadataIndex: int32
    }

    override x.ToString() = "<return>"

    member x.CustomAttrs = x.CustomAttrsStored.GetCustomAttrs x.MetadataIndex

    member x.WithCustomAttrs(customAttrs) =
        { x with
            CustomAttrsStored = storeILCustomAttrs customAttrs
        }

type ILOverridesSpec =
    | OverridesSpec of ILMethodRef * ILType

    member x.MethodRef = let (OverridesSpec(mr, _ty)) = x in mr

    member x.DeclaringType = let (OverridesSpec(_mr, ty)) = x in ty

    override x.ToString() =
        "overrides " + x.DeclaringType.ToString() + "::" + x.MethodRef.ToString()

type ILMethodVirtualInfo =
    {
        IsFinal: bool
        IsNewSlot: bool
        IsCheckAccessOnOverride: bool
        IsAbstract: bool
    }

[<RequireQualifiedAccess>]
type MethodBody =
    | IL of InterruptibleLazy<ILMethodBody>
    | PInvoke of Lazy<PInvokeMethod> (* platform invoke to native *)
    | Abstract
    | Native
    | NotAvailable

[<RequireQualifiedAccess>]
type MethodCodeKind =
    | IL
    | Native
    | Runtime

let typesOfILParams (ps: ILParameters) = ps |> List.map (fun p -> p.Type)

[<StructuralEquality; StructuralComparison>]
type ILGenericVariance =
    | NonVariant
    | CoVariant
    | ContraVariant

[<NoEquality; NoComparison; StructuredFormatDisplay("{DebugText}")>]
type ILGenericParameterDef =
    {
        Name: string
        Constraints: ILTypes
        Variance: ILGenericVariance
        HasReferenceTypeConstraint: bool
        HasNotNullableValueTypeConstraint: bool
        HasDefaultConstructorConstraint: bool
        HasAllowsRefStruct: bool
        CustomAttrsStored: ILAttributesStored
        MetadataIndex: int32
    }

    member x.CustomAttrs = x.CustomAttrsStored.GetCustomAttrs x.MetadataIndex

    /// For debugging
    [<DebuggerBrowsable(DebuggerBrowsableState.Never)>]
    member x.DebugText = x.ToString()

    override x.ToString() = x.Name

type ILGenericParameterDefs = ILGenericParameterDef list

let memberAccessOfFlags flags =
    let f = (flags &&& 0x00000007)

    if f = 0x00000001 then ILMemberAccess.Private
    elif f = 0x00000006 then ILMemberAccess.Public
    elif f = 0x00000004 then ILMemberAccess.Family
    elif f = 0x00000002 then ILMemberAccess.FamilyAndAssembly
    elif f = 0x00000005 then ILMemberAccess.FamilyOrAssembly
    elif f = 0x00000003 then ILMemberAccess.Assembly
    else ILMemberAccess.CompilerControlled

let convertMemberAccess (ilMemberAccess: ILMemberAccess) =
    match ilMemberAccess with
    | ILMemberAccess.Public -> MethodAttributes.Public
    | ILMemberAccess.Private -> MethodAttributes.Private
    | ILMemberAccess.Assembly -> MethodAttributes.Assembly
    | ILMemberAccess.FamilyAndAssembly -> MethodAttributes.FamANDAssem
    | ILMemberAccess.CompilerControlled -> MethodAttributes.PrivateScope
    | ILMemberAccess.FamilyOrAssembly -> MethodAttributes.FamORAssem
    | ILMemberAccess.Family -> MethodAttributes.Family

let inline conditionalAdd condition flagToAdd source =
    if condition then
        source ||| flagToAdd
    else
        source &&& ~~~flagToAdd

let NoMetadataIdx = -1

type InterfaceImpl =
    {
        Idx: int
        Type: ILType
        mutable CustomAttrsStored: ILAttributesStored
    }

    member x.CustomAttrs =
        match x.CustomAttrsStored with
        | ILAttributesStored.Reader f ->
            let res = ILAttributes(f x.Idx)
            x.CustomAttrsStored <- ILAttributesStored.Given res
            res
        | ILAttributesStored.Given attrs -> attrs

    static member Create(ilType: ILType, customAttrsStored: ILAttributesStored) =
        {
            Idx = NoMetadataIdx
            Type = ilType
            CustomAttrsStored = customAttrsStored
        }

    static member Create(ilType: ILType) =
        InterfaceImpl.Create(ilType, emptyILCustomAttrsStored)

[<NoComparison; NoEquality; StructuredFormatDisplay("{DebugText}")>]
type ILMethodDef
    (
        name: string,
        attributes: MethodAttributes,
        implAttributes: MethodImplAttributes,
        callingConv: ILCallingConv,
        parameters: ILParameters,
        ret: ILReturn,
        body: InterruptibleLazy<MethodBody>,
        isEntryPoint: bool,
        genericParams: ILGenericParameterDefs,
        securityDeclsStored: ILSecurityDeclsStored,
        customAttrsStored: ILAttributesStored,
        metadataIndex: int32
    ) =

    new(name, attributes, implAttributes, callingConv, parameters, ret, body, isEntryPoint, genericParams, securityDecls, customAttrs) =
        ILMethodDef(
            name,
            attributes,
            implAttributes,
            callingConv,
            parameters,
            ret,
            body,
            isEntryPoint,
            genericParams,
            storeILSecurityDecls securityDecls,
            storeILCustomAttrs customAttrs,
            NoMetadataIdx
        )

    member private _.LazyBody = body

    // The captured data - remember the object will be as large as the data captured by these members
    member _.Name = name

    member _.Attributes = attributes

    member _.ImplAttributes = implAttributes

    member _.CallingConv = callingConv

    member _.Parameters = parameters

    member _.Return = ret

    member _.Body = body.Value

    member _.SecurityDeclsStored = securityDeclsStored

    member _.IsEntryPoint = isEntryPoint

    member _.GenericParams = genericParams

    member _.CustomAttrsStored = customAttrsStored

    member _.MetadataIndex = metadataIndex

    member x.With
        (
            ?name: string,
            ?attributes: MethodAttributes,
            ?implAttributes: MethodImplAttributes,
            ?callingConv: ILCallingConv,
            ?parameters: ILParameters,
            ?ret: ILReturn,
            ?body: InterruptibleLazy<MethodBody>,
            ?securityDecls: ILSecurityDecls,
            ?isEntryPoint: bool,
            ?genericParams: ILGenericParameterDefs,
            ?customAttrs: ILAttributes
        ) =

        ILMethodDef(
            name = defaultArg name x.Name,
            attributes = defaultArg attributes x.Attributes,
            implAttributes = defaultArg implAttributes x.ImplAttributes,
            callingConv = defaultArg callingConv x.CallingConv,
            parameters = defaultArg parameters x.Parameters,
            ret = defaultArg ret x.Return,
            body = defaultArg body x.LazyBody,
            securityDecls =
                (match securityDecls with
                 | None -> x.SecurityDecls
                 | Some attrs -> attrs),
            isEntryPoint = defaultArg isEntryPoint x.IsEntryPoint,
            genericParams = defaultArg genericParams x.GenericParams,
            customAttrs =
                (match customAttrs with
                 | None -> x.CustomAttrs
                 | Some attrs -> attrs)
        )

    member x.CustomAttrs = x.CustomAttrsStored.GetCustomAttrs metadataIndex

    member x.SecurityDecls = x.SecurityDeclsStored.GetSecurityDecls x.MetadataIndex

    member x.ParameterTypes = typesOfILParams x.Parameters

    member md.Code =
        match md.Body with
        | MethodBody.IL il -> Some il.Value.Code
        | _ -> None

    member x.IsIL =
        match x.Body with
        | MethodBody.IL _ -> true
        | _ -> false

    member x.Locals =
        match x.Body with
        | MethodBody.IL il -> il.Value.Locals
        | _ -> []

    member x.MethodBody =
        match x.Body with
        | MethodBody.IL il -> il.Value
        | _ -> failwith "not IL"

    member x.MaxStack = x.MethodBody.MaxStack

    member x.IsZeroInit = x.MethodBody.IsZeroInit

    member md.GetCallingSignature() =
        mkILCallSig (md.CallingConv, md.ParameterTypes, md.Return.Type)

    member x.IsClassInitializer = x.Name = ".cctor"

    member x.IsConstructor = x.Name = ".ctor"

    member x.Access = memberAccessOfFlags (int x.Attributes)

    member x.IsStatic = x.Attributes &&& MethodAttributes.Static <> enum 0

    member x.IsNonVirtualInstance = not x.IsStatic && not x.IsVirtual

    member x.IsVirtual = x.Attributes &&& MethodAttributes.Virtual <> enum 0

    member x.IsFinal = x.Attributes &&& MethodAttributes.Final <> enum 0

    member x.IsNewSlot = x.Attributes &&& MethodAttributes.NewSlot <> enum 0

    member x.IsCheckAccessOnOverride =
        x.Attributes &&& MethodAttributes.CheckAccessOnOverride <> enum 0

    member x.IsAbstract = x.Attributes &&& MethodAttributes.Abstract <> enum 0

    member x.IsHideBySig = x.Attributes &&& MethodAttributes.HideBySig <> enum 0

    member x.IsSpecialName = x.Attributes &&& MethodAttributes.SpecialName <> enum 0

    member x.IsUnmanagedExport =
        x.Attributes &&& MethodAttributes.UnmanagedExport <> enum 0

    member x.IsReqSecObj = x.Attributes &&& MethodAttributes.RequireSecObject <> enum 0

    member x.HasSecurity = x.Attributes &&& MethodAttributes.HasSecurity <> enum 0

    member x.IsManaged = x.ImplAttributes &&& MethodImplAttributes.Managed <> enum 0

    member x.IsForwardRef = x.ImplAttributes &&& MethodImplAttributes.ForwardRef <> enum 0

    member x.IsInternalCall =
        x.ImplAttributes &&& MethodImplAttributes.InternalCall <> enum 0

    member x.IsPreserveSig =
        x.ImplAttributes &&& MethodImplAttributes.PreserveSig <> enum 0

    member x.IsSynchronized =
        x.ImplAttributes &&& MethodImplAttributes.Synchronized <> enum 0

    member x.IsNoInline = x.ImplAttributes &&& MethodImplAttributes.NoInlining <> enum 0

    member x.IsAggressiveInline =
        x.ImplAttributes &&& MethodImplAttributes.AggressiveInlining <> enum 0

    member x.IsMustRun = x.ImplAttributes &&& MethodImplAttributes.NoOptimization <> enum 0

    member x.WithSpecialName =
        x.With(attributes = (x.Attributes ||| MethodAttributes.SpecialName))

    member x.WithHideBySig() =
        x.With(
            attributes =
                (if x.IsVirtual then
                     x.Attributes &&& ~~~MethodAttributes.CheckAccessOnOverride
                     ||| MethodAttributes.HideBySig
                 else
                     failwith "WithHideBySig")
        )

    member x.WithHideBySig(condition) =
        x.With(attributes = (x.Attributes |> conditionalAdd condition MethodAttributes.HideBySig))

    member x.WithFinal(condition) =
        x.With(attributes = (x.Attributes |> conditionalAdd condition MethodAttributes.Final))

    member x.WithAbstract(condition) =
        x.With(attributes = (x.Attributes |> conditionalAdd condition MethodAttributes.Abstract))

    member x.WithVirtual(condition) =
        x.With(attributes = (x.Attributes |> conditionalAdd condition MethodAttributes.Virtual))

    member x.WithAccess(access) =
        x.With(
            attributes =
                (x.Attributes &&& ~~~MethodAttributes.MemberAccessMask
                 ||| convertMemberAccess access)
        )

    member x.WithNewSlot = x.With(attributes = (x.Attributes ||| MethodAttributes.NewSlot))

    member x.WithSecurity(condition) =
        x.With(attributes = (x.Attributes |> conditionalAdd condition MethodAttributes.HasSecurity))

    member x.WithPInvoke(condition) =
        x.With(attributes = (x.Attributes |> conditionalAdd condition MethodAttributes.PinvokeImpl))

    member x.WithPreserveSig(condition) =
        x.With(implAttributes = (x.ImplAttributes |> conditionalAdd condition MethodImplAttributes.PreserveSig))

    member x.WithSynchronized(condition) =
        x.With(implAttributes = (x.ImplAttributes |> conditionalAdd condition MethodImplAttributes.Synchronized))

    member x.WithNoInlining(condition) =
        x.With(implAttributes = (x.ImplAttributes |> conditionalAdd condition MethodImplAttributes.NoInlining))

    member x.WithAggressiveInlining(condition) =
        x.With(
            implAttributes =
                (x.ImplAttributes
                 |> conditionalAdd condition MethodImplAttributes.AggressiveInlining)
        )

    member x.WithRuntime(condition) =
        x.With(implAttributes = (x.ImplAttributes |> conditionalAdd condition MethodImplAttributes.Runtime))

    [<DebuggerBrowsable(DebuggerBrowsableState.Never)>]
    member x.DebugText = x.ToString()

    override x.ToString() = "method " + x.Name

/// Index table by name and arity.
type MethodDefMap = Map<string, ILMethodDef list>

[<Sealed>]
type ILMethodDefs(f) =
    inherit DelayInitArrayMap<ILMethodDef, string, ILMethodDef list>(f)

    override this.CreateDictionary(arr) =
        let t = Dictionary(arr.Length)

        for i = arr.Length - 1 downto 0 do
            let y = arr[i]
            let key = y.Name

            match t.TryGetValue key with
            | true, m -> t[key] <- y :: m
            | _ -> t[key] <- [ y ]

        t

    interface IEnumerable with
        member x.GetEnumerator() =
            ((x :> IEnumerable<ILMethodDef>).GetEnumerator() :> IEnumerator)

    interface IEnumerable<ILMethodDef> with
        member x.GetEnumerator() =
            (x.GetArray() :> IEnumerable<ILMethodDef>).GetEnumerator()

    member x.AsArray() = x.GetArray()
    member x.AsList() = x.GetArray() |> Array.toList

    member x.FindByName nm =
        match x.GetDictionary().TryGetValue nm with
        | true, m -> m
        | _ -> []

    member x.FindByNameAndArity(nm, arity) =
        x.FindByName nm |> List.filter (fun x -> List.length x.Parameters = arity)

    member x.TryFindInstanceByNameAndCallingSignature(nm, callingSig) =
        x.FindByName nm
        |> List.tryFind (fun x -> not x.IsStatic && x.GetCallingSignature() = callingSig)

[<NoComparison; NoEquality; StructuredFormatDisplay("{DebugText}")>]
type ILEventDef
    (
        eventType: ILType option,
        name: string,
        attributes: EventAttributes,
        addMethod: ILMethodRef,
        removeMethod: ILMethodRef,
        fireMethod: ILMethodRef option,
        otherMethods: ILMethodRef list,
        customAttrsStored: ILAttributesStored,
        metadataIndex: int32
    ) =

    new(eventType, name, attributes, addMethod, removeMethod, fireMethod, otherMethods, customAttrs) =
        ILEventDef(
            eventType,
            name,
            attributes,
            addMethod,
            removeMethod,
            fireMethod,
            otherMethods,
            storeILCustomAttrs customAttrs,
            NoMetadataIdx
        )

    member _.EventType = eventType

    member _.Name = name

    member _.Attributes = attributes

    member _.AddMethod = addMethod

    member _.RemoveMethod = removeMethod

    member _.FireMethod = fireMethod

    member _.OtherMethods = otherMethods

    member _.CustomAttrsStored = customAttrsStored

    member _.MetadataIndex = metadataIndex

    member x.CustomAttrs = customAttrsStored.GetCustomAttrs x.MetadataIndex

    member x.With(?eventType, ?name, ?attributes, ?addMethod, ?removeMethod, ?fireMethod, ?otherMethods, ?customAttrs) =
        ILEventDef(
            eventType = defaultArg eventType x.EventType,
            name = defaultArg name x.Name,
            attributes = defaultArg attributes x.Attributes,
            addMethod = defaultArg addMethod x.AddMethod,
            removeMethod = defaultArg removeMethod x.RemoveMethod,
            fireMethod = defaultArg fireMethod x.FireMethod,
            otherMethods = defaultArg otherMethods x.OtherMethods,
            customAttrs =
                (match customAttrs with
                 | None -> x.CustomAttrs
                 | Some attrs -> attrs)
        )

    member x.IsSpecialName = (x.Attributes &&& EventAttributes.SpecialName) <> enum<_> 0

    member x.IsRTSpecialName =
        (x.Attributes &&& EventAttributes.RTSpecialName) <> enum<_> 0

    /// For debugging
    [<DebuggerBrowsable(DebuggerBrowsableState.Never)>]
    member x.DebugText = x.ToString()

    override x.ToString() = "event " + x.Name

[<NoEquality; NoComparison>]
type ILEventDefs =
    | ILEvents of LazyOrderedMultiMap<string, ILEventDef>

    member x.AsList() = let (ILEvents t) = x in t.Entries()

    member x.LookupByName s = let (ILEvents t) = x in t[s]

    override x.ToString() = "<events>"

[<NoComparison; NoEquality; StructuredFormatDisplay("{DebugText}")>]
type ILPropertyDef
    (
        name: string,
        attributes: PropertyAttributes,
        setMethod: ILMethodRef option,
        getMethod: ILMethodRef option,
        callingConv: ILThisConvention,
        propertyType: ILType,
        init: ILFieldInit option,
        args: ILTypes,
        customAttrsStored: ILAttributesStored,
        metadataIndex: int32
    ) =

    new(name, attributes, setMethod, getMethod, callingConv, propertyType, init, args, customAttrs) =
        ILPropertyDef(
            name,
            attributes,
            setMethod,
            getMethod,
            callingConv,
            propertyType,
            init,
            args,
            storeILCustomAttrs customAttrs,
            NoMetadataIdx
        )

    member x.Name = name
    member x.Attributes = attributes
    member x.GetMethod = getMethod
    member x.SetMethod = setMethod
    member x.CallingConv = callingConv
    member x.PropertyType = propertyType
    member x.Init = init
    member x.Args = args
    member x.CustomAttrsStored = customAttrsStored
    member x.CustomAttrs = customAttrsStored.GetCustomAttrs x.MetadataIndex
    member x.MetadataIndex = metadataIndex

    member x.With(?name, ?attributes, ?setMethod, ?getMethod, ?callingConv, ?propertyType, ?init, ?args, ?customAttrs) =
        ILPropertyDef(
            name = defaultArg name x.Name,
            attributes = defaultArg attributes x.Attributes,
            setMethod = defaultArg setMethod x.SetMethod,
            getMethod = defaultArg getMethod x.GetMethod,
            callingConv = defaultArg callingConv x.CallingConv,
            propertyType = defaultArg propertyType x.PropertyType,
            init = defaultArg init x.Init,
            args = defaultArg args x.Args,
            customAttrs =
                (match customAttrs with
                 | None -> x.CustomAttrs
                 | Some attrs -> attrs)
        )

    member x.IsSpecialName = (x.Attributes &&& PropertyAttributes.SpecialName) <> enum<_> 0

    member x.IsRTSpecialName =
        (x.Attributes &&& PropertyAttributes.RTSpecialName) <> enum<_> 0

    /// For debugging
    [<DebuggerBrowsable(DebuggerBrowsableState.Never)>]
    member x.DebugText = x.ToString()

    override x.ToString() = "property " + x.Name

// Index table by name.
[<NoEquality; NoComparison>]
type ILPropertyDefs =
    | ILProperties of LazyOrderedMultiMap<string, ILPropertyDef>

    member x.AsList() = let (ILProperties t) = x in t.Entries()

    member x.LookupByName s = let (ILProperties t) = x in t[s]

    override x.ToString() = "<properties>"

let convertFieldAccess (ilMemberAccess: ILMemberAccess) =
    match ilMemberAccess with
    | ILMemberAccess.Assembly -> FieldAttributes.Assembly
    | ILMemberAccess.CompilerControlled -> enum<FieldAttributes> 0
    | ILMemberAccess.FamilyAndAssembly -> FieldAttributes.FamANDAssem
    | ILMemberAccess.FamilyOrAssembly -> FieldAttributes.FamORAssem
    | ILMemberAccess.Family -> FieldAttributes.Family
    | ILMemberAccess.Private -> FieldAttributes.Private
    | ILMemberAccess.Public -> FieldAttributes.Public

[<NoComparison; NoEquality; StructuredFormatDisplay("{DebugText}")>]
type ILFieldDef
    (
        name: string,
        fieldType: ILType,
        attributes: FieldAttributes,
        data: byte[] option,
        literalValue: ILFieldInit option,
        offset: int32 option,
        marshal: ILNativeType option,
        customAttrsStored: ILAttributesStored,
        metadataIndex: int32
    ) =

    new(name, fieldType, attributes, data, literalValue, offset, marshal, customAttrs) =
        ILFieldDef(name, fieldType, attributes, data, literalValue, offset, marshal, storeILCustomAttrs customAttrs, NoMetadataIdx)

    member _.Name = name
    member _.FieldType = fieldType
    member _.Attributes = attributes
    member _.Data = data
    member _.LiteralValue = literalValue
    member _.Offset = offset
    member _.Marshal = marshal
    member x.CustomAttrsStored = customAttrsStored
    member x.CustomAttrs = customAttrsStored.GetCustomAttrs x.MetadataIndex
    member x.MetadataIndex = metadataIndex

    member x.With
        (
            ?name: string,
            ?fieldType: ILType,
            ?attributes: FieldAttributes,
            ?data: byte[] option,
            ?literalValue: ILFieldInit option,
            ?offset: int32 option,
            ?marshal: ILNativeType option,
            ?customAttrs: ILAttributes
        ) =
        ILFieldDef(
            name = defaultArg name x.Name,
            fieldType = defaultArg fieldType x.FieldType,
            attributes = defaultArg attributes x.Attributes,
            data = defaultArg data x.Data,
            literalValue = defaultArg literalValue x.LiteralValue,
            offset = defaultArg offset x.Offset,
            marshal = defaultArg marshal x.Marshal,
            customAttrs = defaultArg customAttrs x.CustomAttrs
        )

    member x.IsStatic = x.Attributes &&& FieldAttributes.Static <> enum 0
    member x.IsSpecialName = x.Attributes &&& FieldAttributes.SpecialName <> enum 0
    member x.IsLiteral = x.Attributes &&& FieldAttributes.Literal <> enum 0
    member x.NotSerialized = x.Attributes &&& FieldAttributes.NotSerialized <> enum 0
    member x.IsInitOnly = x.Attributes &&& FieldAttributes.InitOnly <> enum 0
    member x.Access = memberAccessOfFlags (int x.Attributes)

    member x.WithAccess(access) =
        x.With(
            attributes =
                (x.Attributes &&& ~~~FieldAttributes.FieldAccessMask
                 ||| convertFieldAccess access)
        )

    member x.WithInitOnly(condition) =
        x.With(attributes = (x.Attributes |> conditionalAdd condition FieldAttributes.InitOnly))

    member x.WithStatic(condition) =
        x.With(attributes = (x.Attributes |> conditionalAdd condition FieldAttributes.Static))

    member x.WithSpecialName(condition) =
        x.With(
            attributes =
                (x.Attributes
                 |> conditionalAdd condition (FieldAttributes.SpecialName ||| FieldAttributes.RTSpecialName))
        )

    member x.WithNotSerialized(condition) =
        x.With(attributes = (x.Attributes |> conditionalAdd condition FieldAttributes.NotSerialized))

    member x.WithLiteralDefaultValue(literal) =
        x.With(
            literalValue = literal,
            attributes =
                (x.Attributes
                 |> conditionalAdd literal.IsSome (FieldAttributes.Literal ||| FieldAttributes.HasDefault))
        )

    member x.WithFieldMarshal(marshal) =
        x.With(marshal = marshal, attributes = (x.Attributes |> conditionalAdd marshal.IsSome FieldAttributes.HasFieldMarshal))

    [<DebuggerBrowsable(DebuggerBrowsableState.Never)>]
    member x.DebugText = x.ToString()

    override x.ToString() = "field " + x.Name

// Index table by name. Keep a canonical list to make sure field order is not disturbed for binary manipulation.
type ILFieldDefs =
    | ILFields of LazyOrderedMultiMap<string, ILFieldDef>

    member x.AsList() = let (ILFields t) = x in t.Entries()

    member x.LookupByName s = let (ILFields t) = x in t[s]

    override x.ToString() = "<fields>"

type ILMethodImplDef =
    {
        Overrides: ILOverridesSpec
        OverrideBy: ILMethodSpec
    }

// Index table by name and arity.
type ILMethodImplDefs =
    | ILMethodImpls of InterruptibleLazy<MethodImplsMap>

    member x.AsList() =
        let (ILMethodImpls ltab) = x in Map.foldBack (fun _x y r -> y @ r) (ltab.Force()) []

and MethodImplsMap = Map<string * int, ILMethodImplDef list>

[<RequireQualifiedAccess>]
type ILTypeDefLayout =
    | Auto
    | Sequential of ILTypeDefLayoutInfo
    | Explicit of ILTypeDefLayoutInfo (* REVIEW: add field info here *)

and ILTypeDefLayoutInfo =
    {
        Size: int32 option
        Pack: uint16 option
    }

[<RequireQualifiedAccess>]
type ILTypeInit =
    | BeforeField
    | OnAny

[<RequireQualifiedAccess>]
type ILDefaultPInvokeEncoding =
    | Ansi
    | Auto
    | Unicode

type ILTypeDefAccess =
    | Public
    | Private
    | Nested of ILMemberAccess

let typeAccessOfFlags flags =
    let f = (flags &&& 0x00000007)

    if f = 0x00000001 then
        ILTypeDefAccess.Public
    elif f = 0x00000002 then
        ILTypeDefAccess.Nested ILMemberAccess.Public
    elif f = 0x00000003 then
        ILTypeDefAccess.Nested ILMemberAccess.Private
    elif f = 0x00000004 then
        ILTypeDefAccess.Nested ILMemberAccess.Family
    elif f = 0x00000006 then
        ILTypeDefAccess.Nested ILMemberAccess.FamilyAndAssembly
    elif f = 0x00000007 then
        ILTypeDefAccess.Nested ILMemberAccess.FamilyOrAssembly
    elif f = 0x00000005 then
        ILTypeDefAccess.Nested ILMemberAccess.Assembly
    else
        ILTypeDefAccess.Private

let typeEncodingOfFlags flags =
    let f = (flags &&& 0x00030000)

    if f = 0x00020000 then ILDefaultPInvokeEncoding.Auto
    elif f = 0x00010000 then ILDefaultPInvokeEncoding.Unicode
    else ILDefaultPInvokeEncoding.Ansi

[<Flags>]
type ILTypeDefAdditionalFlags =
    | Class = 1
    | ValueType = 2
    | Interface = 4
    | Enum = 8
    | Delegate = 16
    | IsKnownToBeAttribute = 32
    /// The type can contain extension methods,
    /// or this information may not be available at the time the ILTypeDef is created
    | CanContainExtensionMethods = 1024

let internal typeKindFlags =
    ILTypeDefAdditionalFlags.Class
    ||| ILTypeDefAdditionalFlags.ValueType
    ||| ILTypeDefAdditionalFlags.Interface
    ||| ILTypeDefAdditionalFlags.Enum
    ||| ILTypeDefAdditionalFlags.Delegate

let inline internal resetTypeKind flags = flags &&& ~~~typeKindFlags

let (|HasFlag|_|) (flag: ILTypeDefAdditionalFlags) flags = flags &&& flag = flag

let inline typeKindByNames extendsName typeName =
    match extendsName with
    | "System.Enum" -> ILTypeDefAdditionalFlags.Enum
    | "System.Delegate" when typeName <> "System.MulticastDelegate" -> ILTypeDefAdditionalFlags.Delegate
    | "System.MulticastDelegate" -> ILTypeDefAdditionalFlags.Delegate
    | "System.ValueType" when typeName <> "System.Enum" -> ILTypeDefAdditionalFlags.ValueType
    | _ -> ILTypeDefAdditionalFlags.Class

let typeKindOfFlags nm (super: ILType option) flags =
    if (flags &&& 0x00000020) <> 0x0 then
        ILTypeDefAdditionalFlags.Interface
    else
        match super with
        | None -> ILTypeDefAdditionalFlags.Class
        | Some ty ->
            let name = ty.TypeSpec.Name
            typeKindByNames name nm

let convertTypeAccessFlags access =
    match access with
    | ILTypeDefAccess.Public -> TypeAttributes.Public
    | ILTypeDefAccess.Private -> TypeAttributes.NotPublic
    | ILTypeDefAccess.Nested ILMemberAccess.Public -> TypeAttributes.NestedPublic
    | ILTypeDefAccess.Nested ILMemberAccess.Private -> TypeAttributes.NestedPrivate
    | ILTypeDefAccess.Nested ILMemberAccess.Family -> TypeAttributes.NestedFamily
    | ILTypeDefAccess.Nested ILMemberAccess.CompilerControlled -> TypeAttributes.NestedPrivate
    | ILTypeDefAccess.Nested ILMemberAccess.FamilyAndAssembly -> TypeAttributes.NestedFamANDAssem
    | ILTypeDefAccess.Nested ILMemberAccess.FamilyOrAssembly -> TypeAttributes.NestedFamORAssem
    | ILTypeDefAccess.Nested ILMemberAccess.Assembly -> TypeAttributes.NestedAssembly

let convertTypeKind kind =
    match kind with
    | HasFlag ILTypeDefAdditionalFlags.Interface -> TypeAttributes.Abstract ||| TypeAttributes.Interface
    | _ -> TypeAttributes.Class

let convertLayout layout =
    match layout with
    | ILTypeDefLayout.Auto -> TypeAttributes.AutoLayout
    | ILTypeDefLayout.Sequential _ -> TypeAttributes.SequentialLayout
    | ILTypeDefLayout.Explicit _ -> TypeAttributes.ExplicitLayout

let convertEncoding encoding =
    match encoding with
    | ILDefaultPInvokeEncoding.Auto -> TypeAttributes.AutoClass
    | ILDefaultPInvokeEncoding.Ansi -> TypeAttributes.AnsiClass
    | ILDefaultPInvokeEncoding.Unicode -> TypeAttributes.UnicodeClass

let convertToNestedTypeAccess (ilMemberAccess: ILMemberAccess) =
    match ilMemberAccess with
    | ILMemberAccess.Assembly -> TypeAttributes.NestedAssembly
    | ILMemberAccess.CompilerControlled -> failwith "Method access compiler controlled."
    | ILMemberAccess.FamilyAndAssembly -> TypeAttributes.NestedFamANDAssem
    | ILMemberAccess.FamilyOrAssembly -> TypeAttributes.NestedFamORAssem
    | ILMemberAccess.Family -> TypeAttributes.NestedFamily
    | ILMemberAccess.Private -> TypeAttributes.NestedPrivate
    | ILMemberAccess.Public -> TypeAttributes.NestedPublic

let convertInitSemantics (init: ILTypeInit) =
    match init with
    | ILTypeInit.BeforeField -> TypeAttributes.BeforeFieldInit
    | ILTypeInit.OnAny -> enum 0

let emptyILExtends = notlazy<ILType option> None

[<NoComparison; NoEquality; StructuredFormatDisplay("{DebugText}")>]
type ILTypeDef
    (
        name: string,
        attributes: TypeAttributes,
        layout: ILTypeDefLayout,
        implements: InterruptibleLazy<InterfaceImpl list>,
        genericParams: ILGenericParameterDefs,
        extends: InterruptibleLazy<ILType option>,
        methods: ILMethodDefs,
        nestedTypes: ILTypeDefs,
        fields: ILFieldDefs,
        methodImpls: ILMethodImplDefs,
        events: ILEventDefs,
        properties: ILPropertyDefs,
        additionalFlags: ILTypeDefAdditionalFlags,
        securityDeclsStored: ILSecurityDeclsStored,
        customAttrsStored: ILAttributesStored,
        metadataIndex: int32
    ) =

    let mutable customAttrsStored = customAttrsStored

    let hasFlag flag = additionalFlags &&& flag = flag

    new
        (
            name,
            attributes,
            layout,
            implements,
            genericParams,
            extends,
            methods,
            nestedTypes,
            fields,
            methodImpls,
            events,
            properties,
            additionalFlags,
            securityDecls,
            customAttrs
        ) =
        ILTypeDef(
            name,
            attributes,
            layout,
            implements,
            genericParams,
            extends,
            methods,
            nestedTypes,
            fields,
            methodImpls,
            events,
            properties,
            additionalFlags,
            storeILSecurityDecls securityDecls,
            customAttrs,
            NoMetadataIdx
        )

    new
        (
            name,
            attributes,
            layout,
            implements,
            genericParams,
            extends,
            methods,
            nestedTypes,
            fields,
            methodImpls,
            events,
            properties,
            securityDecls,
            customAttrs
        ) =
        let additionalFlags =
            ILTypeDefAdditionalFlags.CanContainExtensionMethods
            ||| typeKindOfFlags name extends (int attributes)

        ILTypeDef(
            name,
            attributes,
            layout,
            InterruptibleLazy.FromValue(implements),
            genericParams,
            InterruptibleLazy.FromValue(extends),
            methods,
            nestedTypes,
            fields,
            methodImpls,
            events,
            properties,
            additionalFlags,
            storeILSecurityDecls securityDecls,
            customAttrs,
            NoMetadataIdx
        )

    member _.Name = name

    member _.Attributes = attributes

    member _.GenericParams = genericParams

    member _.Layout = layout

    member _.NestedTypes = nestedTypes

    member _.Implements = implements

    member _.Extends = extends

    member _.Methods = methods

    member _.SecurityDeclsStored = securityDeclsStored

    member _.Fields = fields

    member _.MethodImpls = methodImpls

    member _.Events = events

    member _.Properties = properties

    member _.IsKnownToBeAttribute = hasFlag ILTypeDefAdditionalFlags.IsKnownToBeAttribute

    member _.CanContainExtensionMethods =
        hasFlag ILTypeDefAdditionalFlags.CanContainExtensionMethods

    member _.CustomAttrsStored = customAttrsStored

    member _.MetadataIndex = metadataIndex

    member x.With
        (
            ?name,
            ?attributes,
            ?layout,
            ?implements,
            ?genericParams,
            ?extends,
            ?methods,
            ?nestedTypes,
            ?fields,
            ?methodImpls,
            ?events,
            ?properties,
            ?newAdditionalFlags,
            ?customAttrs,
            ?securityDecls
        ) =
        ILTypeDef(
            name = defaultArg name x.Name,
            attributes = defaultArg attributes x.Attributes,
            layout = defaultArg layout x.Layout,
            genericParams = defaultArg genericParams x.GenericParams,
            nestedTypes = defaultArg nestedTypes x.NestedTypes,
            implements = defaultArg implements x.Implements,
            extends = defaultArg extends x.Extends,
            methods = defaultArg methods x.Methods,
            securityDecls = defaultArg securityDecls x.SecurityDecls,
            fields = defaultArg fields x.Fields,
            methodImpls = defaultArg methodImpls x.MethodImpls,
            events = defaultArg events x.Events,
            properties = defaultArg properties x.Properties,
            additionalFlags = defaultArg newAdditionalFlags additionalFlags,
            customAttrs = defaultArg customAttrs x.CustomAttrsStored
        )

    member x.CustomAttrs: ILAttributes =
        match customAttrsStored with
        | ILAttributesStored.Reader f ->
            let res = ILAttributes(f x.MetadataIndex)
            customAttrsStored <- ILAttributesStored.Given res
            res
        | ILAttributesStored.Given res -> res

    member x.SecurityDecls = x.SecurityDeclsStored.GetSecurityDecls x.MetadataIndex

    member x.IsClass = hasFlag ILTypeDefAdditionalFlags.Class

    member x.IsStruct = hasFlag ILTypeDefAdditionalFlags.ValueType

    member x.IsInterface = hasFlag ILTypeDefAdditionalFlags.Interface

    member x.IsEnum = hasFlag ILTypeDefAdditionalFlags.Enum

    member x.IsDelegate = hasFlag ILTypeDefAdditionalFlags.Delegate

    member x.Access = typeAccessOfFlags (int x.Attributes)
    member x.IsAbstract = x.Attributes &&& TypeAttributes.Abstract <> enum 0
    member x.IsSealed = x.Attributes &&& TypeAttributes.Sealed <> enum 0
    member x.IsSerializable = x.Attributes &&& TypeAttributes.Serializable <> enum 0

    member x.IsComInterop =
        x.Attributes &&& TypeAttributes.Import
        <> enum 0 (* Class or interface generated for COM interop *)

    member x.IsSpecialName = x.Attributes &&& TypeAttributes.SpecialName <> enum 0
    member x.HasSecurity = x.Attributes &&& TypeAttributes.HasSecurity <> enum 0
    member x.Encoding = typeEncodingOfFlags (int x.Attributes)
    member x.IsStructOrEnum = x.IsStruct || x.IsEnum

    member x.WithAccess(access) =
        x.With(
            attributes =
                (x.Attributes &&& ~~~TypeAttributes.VisibilityMask
                 ||| convertTypeAccessFlags access)
        )

    member x.WithNestedAccess(access) =
        x.With(
            attributes =
                (x.Attributes &&& ~~~TypeAttributes.VisibilityMask
                 ||| convertToNestedTypeAccess access)
        )

    member x.WithSealed(condition) =
        x.With(attributes = (x.Attributes |> conditionalAdd condition TypeAttributes.Sealed))

    member x.WithSerializable(condition) =
        x.With(attributes = (x.Attributes |> conditionalAdd condition TypeAttributes.Serializable))

    member x.WithAbstract(condition) =
        x.With(attributes = (x.Attributes |> conditionalAdd condition TypeAttributes.Abstract))

    member x.WithImport(condition) =
        x.With(attributes = (x.Attributes |> conditionalAdd condition TypeAttributes.Import))

    member x.WithHasSecurity(condition) =
        x.With(attributes = (x.Attributes |> conditionalAdd condition TypeAttributes.HasSecurity))

    member x.WithLayout(layout) =
        x.With(attributes = (x.Attributes ||| convertLayout layout), layout = layout)

    member x.WithKind(kind) =
        x.With(
            attributes = (x.Attributes ||| convertTypeKind kind),
            newAdditionalFlags = (resetTypeKind additionalFlags ||| kind),
            extends =
                match kind with
                | HasFlag ILTypeDefAdditionalFlags.Interface -> emptyILExtends
                | _ -> x.Extends
        )

    member x.WithEncoding(encoding) =
        x.With(attributes = (x.Attributes &&& ~~~TypeAttributes.StringFormatMask ||| convertEncoding encoding))

    member x.WithSpecialName(condition) =
        x.With(attributes = (x.Attributes |> conditionalAdd condition TypeAttributes.SpecialName))

    member x.WithInitSemantics(init) =
        x.With(attributes = (x.Attributes ||| convertInitSemantics init))

    member x.WithIsKnownToBeAttribute() =
        x.With(newAdditionalFlags = (additionalFlags ||| ILTypeDefAdditionalFlags.IsKnownToBeAttribute))

    [<DebuggerBrowsable(DebuggerBrowsableState.Never)>]
    member x.DebugText = x.ToString()

    override x.ToString() = "type " + x.Name

and [<Sealed>] ILTypeDefs(f: unit -> ILPreTypeDef[]) =
    inherit DelayInitArrayMap<ILPreTypeDef, string list * string, ILPreTypeDef>(f)

    override this.CreateDictionary(arr) =
        let t = Dictionary(arr.Length, HashIdentity.Structural)

        for pre in arr do
            let key = pre.Namespace, pre.Name
            t[key] <- pre

#if FABLE_COMPILER
        t
#else
        ReadOnlyDictionary t
#endif

    member x.AsArray() =
        [| for pre in x.GetArray() -> pre.GetTypeDef() |]

    member x.AsList() =
        [ for pre in x.GetArray() -> pre.GetTypeDef() ]

    interface IEnumerable with
        member x.GetEnumerator() =
            ((x :> IEnumerable<ILTypeDef>).GetEnumerator() :> IEnumerator)

    interface IEnumerable<ILTypeDef> with
        member x.GetEnumerator() =
            (seq { for pre in x.GetArray() -> pre.GetTypeDef() }).GetEnumerator()

    member x.AsArrayOfPreTypeDefs() = x.GetArray()

    member x.FindByName nm =
        let ns, n = splitILTypeName nm
        x.GetDictionary().[(ns, n)].GetTypeDef()

    member x.ExistsByName nm =
        let ns, n = splitILTypeName nm
        x.GetDictionary().ContainsKey((ns, n))

and [<NoEquality; NoComparison>] ILPreTypeDef =
    abstract Namespace: string list
    abstract Name: string
    abstract GetTypeDef: unit -> ILTypeDef

/// This is a memory-critical class. Very many of these objects get allocated and held to represent the contents of .NET assemblies.
and [<Sealed>] ILPreTypeDefImpl(nameSpace: string list, name: string, metadataIndex: int32, storage: ILTypeDefStored) =
    let stored =
        lazy
            match storage with
            | ILTypeDefStored.Given td -> td
            | ILTypeDefStored.Computed f -> f ()
            | ILTypeDefStored.Reader f -> f metadataIndex

    interface ILPreTypeDef with
        member _.Namespace = nameSpace
        member _.Name = name
        member x.GetTypeDef() = stored.Value

and ILTypeDefStored =
    | Given of ILTypeDef
    | Reader of (int32 -> ILTypeDef)
    | Computed of (unit -> ILTypeDef)

let mkILTypeDefReader f = ILTypeDefStored.Reader f

type ILNestedExportedType =
    {
        Name: string
        Access: ILMemberAccess
        Nested: ILNestedExportedTypes
        CustomAttrsStored: ILAttributesStored
        MetadataIndex: int32
    }

    member x.CustomAttrs = x.CustomAttrsStored.GetCustomAttrs x.MetadataIndex

    override x.ToString() = "exported type " + x.Name

and ILNestedExportedTypes =
    | ILNestedExportedTypes of InterruptibleLazy<Map<string, ILNestedExportedType>>

    member x.AsList() =
        let (ILNestedExportedTypes ltab) = x in Map.foldBack (fun _x y r -> y :: r) (ltab.Force()) []

and [<NoComparison; NoEquality>] ILExportedTypeOrForwarder =
    {
        ScopeRef: ILScopeRef
        Name: string
        Attributes: TypeAttributes
        Nested: ILNestedExportedTypes
        CustomAttrsStored: ILAttributesStored
        MetadataIndex: int32
    }

    member x.Access = typeAccessOfFlags (int x.Attributes)

    member x.IsForwarder = x.Attributes &&& enum<TypeAttributes> 0x00200000 <> enum 0

    member x.CustomAttrs = x.CustomAttrsStored.GetCustomAttrs x.MetadataIndex

    override x.ToString() = "exported type " + x.Name

and ILExportedTypesAndForwarders =
    | ILExportedTypesAndForwarders of InterruptibleLazy<Map<string, ILExportedTypeOrForwarder>>

    member x.AsList() =
        let (ILExportedTypesAndForwarders ltab) = x in Map.foldBack (fun _x y r -> y :: r) (ltab.Force()) []

    member x.TryFindByName nm =
        match x with
        | ILExportedTypesAndForwarders ltab -> ltab.Value.TryFind nm

[<RequireQualifiedAccess>]
type ILResourceAccess =
    | Public
    | Private

[<RequireQualifiedAccess; NoEquality; NoComparison>]
type ILResourceLocation =
#if FABLE_COMPILER
    | Local of ByteMemory
#else
    | Local of ByteStorage
#endif
    | File of ILModuleRef * int32
    | Assembly of ILAssemblyRef

type ILResource =
    {
        Name: string
        Location: ILResourceLocation
        Access: ILResourceAccess
        CustomAttrsStored: ILAttributesStored
        MetadataIndex: int32
    }

    /// Read the bytes from a resource local to an assembly
    member r.GetBytes() =
        match r.Location with
#if FABLE_COMPILER
        | ILResourceLocation.Local bytes -> bytes.AsReadOnly()
#else
        | ILResourceLocation.Local bytes -> bytes.GetByteMemory()
#endif
        | _ -> failwith "GetBytes"

    member x.CustomAttrs = x.CustomAttrsStored.GetCustomAttrs x.MetadataIndex

    override x.ToString() = "resource " + x.Name

type ILResources =
    | ILResources of ILResource list

    member x.AsList() = let (ILResources ltab) = x in ltab

// --------------------------------------------------------------------
// One module in the "current" assembly
// --------------------------------------------------------------------

[<RequireQualifiedAccess>]
type ILAssemblyLongevity =
    | Unspecified
    | Library
    | PlatformAppDomain
    | PlatformProcess
    | PlatformSystem

    static member Default = Unspecified

type ILAssemblyManifest =
    {
        Name: string
        AuxModuleHashAlgorithm: int32
        SecurityDeclsStored: ILSecurityDeclsStored
        PublicKey: byte[] option
        Version: ILVersionInfo option
        Locale: Locale option
        CustomAttrsStored: ILAttributesStored

        AssemblyLongevity: ILAssemblyLongevity
        DisableJitOptimizations: bool
        JitTracking: bool
        IgnoreSymbolStoreSequencePoints: bool
        Retargetable: bool

        /// Records the types implemented by other modules.
        ExportedTypes: ILExportedTypesAndForwarders

        /// Records whether the entrypoint resides in another module.
        EntrypointElsewhere: ILModuleRef option
        MetadataIndex: int32
    }

    member x.CustomAttrs = x.CustomAttrsStored.GetCustomAttrs x.MetadataIndex

    member x.SecurityDecls = x.SecurityDeclsStored.GetSecurityDecls x.MetadataIndex

    override x.ToString() = "assembly manifest " + x.Name

[<RequireQualifiedAccess>]
type ILNativeResource =
    | In of fileName: string * linkedResourceBase: int * linkedResourceStart: int * linkedResourceLength: int
    | Out of unlinkedResource: byte[]

type ILModuleDef =
    {
        Manifest: ILAssemblyManifest option
        Name: string
        TypeDefs: ILTypeDefs
        SubsystemVersion: int * int
        UseHighEntropyVA: bool
        SubSystemFlags: int32
        IsDLL: bool
        IsILOnly: bool
        Platform: ILPlatform option
        StackReserveSize: int32 option
        Is32Bit: bool
        Is32BitPreferred: bool
        Is64Bit: bool
        VirtualAlignment: int32
        PhysicalAlignment: int32
        ImageBase: int32
        MetadataVersion: string
        Resources: ILResources
        /// e.g. win32 resources
        NativeResources: ILNativeResource list
        CustomAttrsStored: ILAttributesStored
        MetadataIndex: int32
    }

    member x.ManifestOfAssembly =
        match x.Manifest with
        | Some m -> m
        | None -> failwith "no manifest"

    member m.HasManifest =
        match m.Manifest with
        | None -> false
        | _ -> true

    member x.CustomAttrs = x.CustomAttrsStored.GetCustomAttrs x.MetadataIndex

    override x.ToString() = "assembly " + x.Name

// --------------------------------------------------------------------
// Add fields and types to tables, with decent error messages
// when clashes occur...
// --------------------------------------------------------------------

let mkILEmptyGenericParams = ([]: ILGenericParameterDefs)

let emptyILGenericArgsList = ([]: ILType list)

// --------------------------------------------------------------------
// Make ILTypeRefs etc.
// --------------------------------------------------------------------

let mkILNestedTyRef (scope, l, nm) = ILTypeRef.Create(scope, l, nm)

let mkILTyRef (scope, nm) = mkILNestedTyRef (scope, [], nm)

type ILGenericArgsList = ILType list

let mkILTySpec (tref, inst) = ILTypeSpec.Create(tref, inst)

let mkILNonGenericTySpec tref = mkILTySpec (tref, [])

let mkILTyRefInTyRef (tref: ILTypeRef, nm) =
    mkILNestedTyRef (tref.Scope, tref.Enclosing @ [ tref.Name ], nm)

let mkILTy boxed tspec =
    match boxed with
    | AsObject -> mkILBoxedType tspec
    | _ -> ILType.Value tspec

let mkILNamedTy vc tref tinst =
    mkILTy vc (ILTypeSpec.Create(tref, tinst))

let mkILValueTy tref tinst = mkILNamedTy AsValue tref tinst

let mkILBoxedTy tref tinst = mkILNamedTy AsObject tref tinst

let mkILNonGenericValueTy tref = mkILNamedTy AsValue tref []

let mkILNonGenericBoxedTy tref = mkILNamedTy AsObject tref []

let mkSimpleAssemblyRef n =
    ILAssemblyRef.Create(n, None, None, false, None, None)

let mkSimpleModRef n = ILModuleRef.Create(n, true, None)

// --------------------------------------------------------------------
// The toplevel class of a module is called "<Module>"
// --------------------------------------------------------------------

let typeNameForGlobalFunctions = "<Module>"

let mkILTypeForGlobalFunctions scoref =
    mkILBoxedType (mkILNonGenericTySpec (ILTypeRef.Create(scoref, [], typeNameForGlobalFunctions)))

let isTypeNameForGlobalFunctions d = (d = typeNameForGlobalFunctions)

let mkILMethRef (tref, callconv, nm, numGenericParams, argTys, retTy) =
    {
        mrefParent = tref
        mrefCallconv = callconv
        mrefGenericArity = numGenericParams
        mrefName = nm
        mrefArgs = argTys
        mrefReturn = retTy
    }

let mkILMethSpecForMethRefInTy (mref, ty, methInst) =
    {
        mspecMethodRef = mref
        mspecDeclaringType = ty
        mspecMethodInst = methInst
    }

let mkILMethSpec (mref, vc, tinst, methInst) =
    mkILMethSpecForMethRefInTy (mref, mkILNamedTy vc mref.DeclaringTypeRef tinst, methInst)

let mkILMethSpecInTypeRef (tref, vc, cc, nm, argTys, retTy, tinst, methInst) =
    mkILMethSpec (mkILMethRef (tref, cc, nm, List.length methInst, argTys, retTy), vc, tinst, methInst)

let mkILMethSpecInTy (ty: ILType, cc, nm, argTys, retTy, methInst: ILGenericArgs) =
    mkILMethSpecForMethRefInTy (mkILMethRef (ty.TypeRef, cc, nm, methInst.Length, argTys, retTy), ty, methInst)

let mkILNonGenericMethSpecInTy (ty, cc, nm, argTys, retTy) =
    mkILMethSpecInTy (ty, cc, nm, argTys, retTy, [])

let mkILInstanceMethSpecInTy (ty: ILType, nm, argTys, retTy, methInst) =
    mkILMethSpecInTy (ty, ILCallingConv.Instance, nm, argTys, retTy, methInst)

let mkILNonGenericInstanceMethSpecInTy (ty: ILType, nm, argTys, retTy) =
    mkILInstanceMethSpecInTy (ty, nm, argTys, retTy, [])

let mkILStaticMethSpecInTy (ty, nm, argTys, retTy, methInst) =
    mkILMethSpecInTy (ty, ILCallingConv.Static, nm, argTys, retTy, methInst)

let mkILNonGenericStaticMethSpecInTy (ty, nm, argTys, retTy) =
    mkILStaticMethSpecInTy (ty, nm, argTys, retTy, [])

let mkILCtorMethSpec (tref, argTys, tinst) =
    mkILMethSpecInTypeRef (tref, AsObject, ILCallingConv.Instance, ".ctor", argTys, ILType.Void, tinst, [])

let mkILCtorMethSpecForTy (ty, args) =
    mkILMethSpecInTy (ty, ILCallingConv.Instance, ".ctor", args, ILType.Void, [])

let mkILNonGenericCtorMethSpec (tref, args) = mkILCtorMethSpec (tref, args, [])

// --------------------------------------------------------------------
// Make references to fields
// --------------------------------------------------------------------

let mkILFieldRef (tref, nm, ty) =
    {
        DeclaringTypeRef = tref
        Name = nm
        Type = ty
    }

let mkILFieldSpec (tref, ty) = { FieldRef = tref; DeclaringType = ty }

let mkILFieldSpecInTy (ty: ILType, nm, fty) =
    mkILFieldSpec (mkILFieldRef (ty.TypeRef, nm, fty), ty)

let andTailness x y =
    match x with
    | Tailcall when y -> Tailcall
    | _ -> Normalcall

// --------------------------------------------------------------------
// Basic operations on code.
// --------------------------------------------------------------------

let formatCodeLabel (x: int) = "L" + string x

//  ++GLOBAL MUTABLE STATE (concurrency safe)
let codeLabelCount = ref 0
#if FABLE_COMPILER
let generateCodeLabel () = codeLabelCount.Value <- codeLabelCount.Value + 1; codeLabelCount.Value
#else
let generateCodeLabel () = Interlocked.Increment codeLabelCount
#endif

let instrIsRet i =
    match i with
    | I_ret -> true
    | _ -> false

let nonBranchingInstrsToCode instrs : ILCode =
    let instrs = Array.ofList instrs

    let instrs =
        if instrs.Length <> 0 && instrIsRet (Array.last instrs) then
            instrs
        else
            Array.append instrs [| I_ret |]

    {
        Labels = Dictionary()
        Instrs = instrs
        Exceptions = []
        Locals = []
    }

// --------------------------------------------------------------------
//
// --------------------------------------------------------------------

let mkILTyvarTy tv = ILType.TypeVar tv

let mkILSimpleTypar nm =
    {
        Name = nm
        Constraints = []
        Variance = NonVariant
        HasReferenceTypeConstraint = false
        HasNotNullableValueTypeConstraint = false
        HasDefaultConstructorConstraint = false
        HasAllowsRefStruct = false
        CustomAttrsStored = storeILCustomAttrs emptyILCustomAttrs
        MetadataIndex = NoMetadataIdx
    }

let genericParamOfGenericActual (_ga: ILType) = mkILSimpleTypar "T"

let mkILFormalTypars (x: ILGenericArgsList) = List.map genericParamOfGenericActual x

let mkILFormalGenericArgs numtypars (gparams: ILGenericParameterDefs) =
    List.mapi (fun n _gf -> mkILTyvarTy (uint16 (numtypars + n))) gparams

let mkILFormalBoxedTy tref gparams =
    mkILBoxedTy tref (mkILFormalGenericArgs 0 gparams)

let mkILFormalNamedTy bx tref gparams =
    mkILNamedTy bx tref (mkILFormalGenericArgs 0 gparams)

// --------------------------------------------------------------------
// Operations on class etc. defs.
// --------------------------------------------------------------------

let mkRefForNestedILTypeDef scope (enc: ILTypeDef list, td: ILTypeDef) =
    mkILNestedTyRef (scope, (enc |> List.map (fun etd -> etd.Name)), td.Name)

// --------------------------------------------------------------------
// Operations on type tables.
// --------------------------------------------------------------------

let mkILPreTypeDef (td: ILTypeDef) =
    let ns, n = splitILTypeName td.Name
    ILPreTypeDefImpl(ns, n, NoMetadataIdx, ILTypeDefStored.Given td) :> ILPreTypeDef

let mkILPreTypeDefComputed (ns, n, f) =
    ILPreTypeDefImpl(ns, n, NoMetadataIdx, ILTypeDefStored.Computed f) :> ILPreTypeDef

let mkILPreTypeDefRead (ns, n, idx, f) =
    ILPreTypeDefImpl(ns, n, idx, f) :> ILPreTypeDef

let addILTypeDef td (tdefs: ILTypeDefs) =
    ILTypeDefs(fun () -> [| yield mkILPreTypeDef td; yield! tdefs.AsArrayOfPreTypeDefs() |])

let mkILTypeDefsFromArray (l: ILTypeDef[]) =
    ILTypeDefs(fun () -> Array.map mkILPreTypeDef l)

let mkILTypeDefs l = mkILTypeDefsFromArray (Array.ofList l)
let mkILTypeDefsComputed f = ILTypeDefs f
let emptyILTypeDefs = mkILTypeDefsFromArray [||]

let emptyILInterfaceImpls = InterruptibleLazy<InterfaceImpl list>.FromValue([])

// --------------------------------------------------------------------
// Operations on method tables.
// --------------------------------------------------------------------

let mkILMethodsFromArray xs = ILMethodDefs(fun () -> xs)

let mkILMethods xs =
    xs |> Array.ofList |> mkILMethodsFromArray

let mkILMethodsComputed f = ILMethodDefs f
let emptyILMethods = mkILMethodsFromArray [||]

// --------------------------------------------------------------------
// Operations and defaults for modules, assemblies etc.
// --------------------------------------------------------------------

let defaultSubSystem = 3 (* this is what comes out of ILDASM on 30/04/2001 *)
let defaultPhysAlignment = 512 (* this is what comes out of ILDASM on 30/04/2001 *)

let defaultVirtAlignment =
    0x2000 (* this is what comes out of ILDASM on 30/04/2001 *)

let defaultImageBase =
    0x034f0000 (* this is what comes out of ILDASM on 30/04/2001 *)

// --------------------------------------------------------------------
// Array types
// --------------------------------------------------------------------

let mkILArrTy (ty, shape) = ILType.Array(shape, ty)

let mkILArr1DTy ty =
    mkILArrTy (ty, ILArrayShape.SingleDimensional)

let isILArrTy ty =
    match ty with
    | ILType.Array _ -> true
    | _ -> false

let destILArrTy ty =
    match ty with
    | ILType.Array(shape, ty) -> (shape, ty)
    | _ -> failwith "destILArrTy"

// --------------------------------------------------------------------
// Sigs of special types built-in
// --------------------------------------------------------------------

[<Literal>]
let tname_Attribute = "System.Attribute"

[<Literal>]
let tname_Enum = "System.Enum"

[<Literal>]
let tname_SealedAttribute = "System.SealedAttribute"

[<Literal>]
let tname_Object = "System.Object"

[<Literal>]
let tname_String = "System.String"

[<Literal>]
let tname_Array = "System.Array"

[<Literal>]
let tname_Type = "System.Type"

[<Literal>]
let tname_Int64 = "System.Int64"

[<Literal>]
let tname_UInt64 = "System.UInt64"

[<Literal>]
let tname_Int32 = "System.Int32"

[<Literal>]
let tname_UInt32 = "System.UInt32"

[<Literal>]
let tname_Int16 = "System.Int16"

[<Literal>]
let tname_UInt16 = "System.UInt16"

[<Literal>]
let tname_SByte = "System.SByte"

[<Literal>]
let tname_Byte = "System.Byte"

[<Literal>]
let tname_Single = "System.Single"

[<Literal>]
let tname_Double = "System.Double"

[<Literal>]
let tname_Bool = "System.Boolean"

[<Literal>]
let tname_Char = "System.Char"

[<Literal>]
let tname_IntPtr = "System.IntPtr"

[<Literal>]
let tname_UIntPtr = "System.UIntPtr"

[<Literal>]
let tname_TypedReference = "System.TypedReference"

[<NoEquality; NoComparison; StructuredFormatDisplay("{DebugText}")>]
type ILGlobals(primaryScopeRef: ILScopeRef, equivPrimaryAssemblyRefs: ILAssemblyRef list, fsharpCoreAssemblyScopeRef: ILScopeRef) =

    let equivPrimaryAssemblyRefs = Array.ofList equivPrimaryAssemblyRefs

    let mkSysILTypeRef nm = mkILTyRef (primaryScopeRef, nm)

    let byteIlType = ILType.Value(mkILNonGenericTySpec (mkSysILTypeRef tname_Byte))

    let stringIlType =
        mkILBoxedType (mkILNonGenericTySpec (mkSysILTypeRef tname_String))

    member _.primaryAssemblyScopeRef = primaryScopeRef

    member x.primaryAssemblyRef =
        match primaryScopeRef with
        | ILScopeRef.Assembly aref -> aref
        | _ -> failwith "Invalid primary assembly"

    member x.primaryAssemblyName = x.primaryAssemblyRef.Name

    member val typ_Attribute = mkILBoxedType (mkILNonGenericTySpec (mkSysILTypeRef tname_Attribute))

    member val typ_Enum = mkILBoxedType (mkILNonGenericTySpec (mkSysILTypeRef tname_Enum))

    member val typ_SealedAttribute = mkILBoxedType (mkILNonGenericTySpec (mkSysILTypeRef tname_SealedAttribute))

    member val typ_Object = mkILBoxedType (mkILNonGenericTySpec (mkSysILTypeRef tname_Object))

    member val typ_String = stringIlType

    member val typ_Array = mkILBoxedType (mkILNonGenericTySpec (mkSysILTypeRef tname_Array))

    member val typ_Type = mkILBoxedType (mkILNonGenericTySpec (mkSysILTypeRef tname_Type))

    member val typ_SByte = ILType.Value(mkILNonGenericTySpec (mkSysILTypeRef tname_SByte))

    member val typ_Int16 = ILType.Value(mkILNonGenericTySpec (mkSysILTypeRef tname_Int16))

    member val typ_Int32 = ILType.Value(mkILNonGenericTySpec (mkSysILTypeRef tname_Int32))

    member val typ_Int64 = ILType.Value(mkILNonGenericTySpec (mkSysILTypeRef tname_Int64))

    member val typ_Byte = byteIlType

    member val typ_ByteArray = ILType.Array(ILArrayShape.SingleDimensional, byteIlType)

    member val typ_StringArray = ILType.Array(ILArrayShape.SingleDimensional, stringIlType)

    member val typ_UInt16 = ILType.Value(mkILNonGenericTySpec (mkSysILTypeRef tname_UInt16))

    member val typ_UInt32 = ILType.Value(mkILNonGenericTySpec (mkSysILTypeRef tname_UInt32))

    member val typ_UInt64 = ILType.Value(mkILNonGenericTySpec (mkSysILTypeRef tname_UInt64))

    member val typ_Single = ILType.Value(mkILNonGenericTySpec (mkSysILTypeRef tname_Single))

    member val typ_Double = ILType.Value(mkILNonGenericTySpec (mkSysILTypeRef tname_Double))

    member val typ_Bool = ILType.Value(mkILNonGenericTySpec (mkSysILTypeRef tname_Bool))

    member val typ_Char = ILType.Value(mkILNonGenericTySpec (mkSysILTypeRef tname_Char))

    member val typ_IntPtr = ILType.Value(mkILNonGenericTySpec (mkSysILTypeRef tname_IntPtr))

    member val typ_UIntPtr = ILType.Value(mkILNonGenericTySpec (mkSysILTypeRef tname_UIntPtr))

    member val typ_TypedReference = ILType.Value(mkILNonGenericTySpec (mkSysILTypeRef tname_TypedReference))

    member _.fsharpCoreAssemblyScopeRef = fsharpCoreAssemblyScopeRef

    member x.IsPossiblePrimaryAssemblyRef(aref: ILAssemblyRef) =
        aref.EqualsIgnoringVersion x.primaryAssemblyRef
        || equivPrimaryAssemblyRefs |> Array.exists aref.EqualsIgnoringVersion

    /// For debugging
    [<DebuggerBrowsable(DebuggerBrowsableState.Never)>]
    member x.DebugText = x.ToString()

    override x.ToString() = "<ILGlobals>"

let mkILGlobals (primaryScopeRef, equivPrimaryAssemblyRefs, fsharpCoreAssemblyScopeRef) =
    ILGlobals(primaryScopeRef, equivPrimaryAssemblyRefs, fsharpCoreAssemblyScopeRef)

let mkNormalCall mspec = I_call(Normalcall, mspec, None)

let mkNormalCallvirt mspec = I_callvirt(Normalcall, mspec, None)

let mkNormalNewobj mspec = I_newobj(mspec, None)

/// Comment on common object cache sizes:
/// mkLdArg - I can't imagine any IL method we generate needing more than this
/// mkLdLoc - I tried 256, and there were LdLoc allocations left, so I upped it o 512. I didn't check again.
/// mkStLoc - it should be the same as LdLoc (where there's a LdLoc there must be a StLoc)
/// mkLdcInt32 - just a guess

let ldargs = [| for i in 0..128 -> I_ldarg(uint16 i) |]

let mkLdarg i =
    if 0us < i && i < uint16 ldargs.Length then
        ldargs[int i]
    else
        I_ldarg i

let mkLdarg0 = mkLdarg 0us

let ldlocs = [| for i in 0..512 -> I_ldloc(uint16 i) |]

let mkLdloc i =
    if 0us < i && i < uint16 ldlocs.Length then
        ldlocs[int i]
    else
        I_ldloc i

let stlocs = [| for i in 0..512 -> I_stloc(uint16 i) |]

let mkStloc i =
    if 0us < i && i < uint16 stlocs.Length then
        stlocs[int i]
    else
        I_stloc i

let ldi32s = [| for i in 0..256 -> AI_ldc(DT_I4, ILConst.I4 i) |]

let mkLdcInt32 i =
    if 0 < i && i < ldi32s.Length then
        ldi32s[i]
    else
        AI_ldc(DT_I4, ILConst.I4 i)

(* NOTE: ecma_ prefix refers to the standard "mscorlib" *)
let ecmaPublicKey =
    PublicKeyToken(Bytes.ofInt32Array [| 0xde; 0xad; 0xbe; 0xef; 0xca; 0xfe; 0xfa; 0xce |])

let isILBoxedTy =
    function
    | ILType.Boxed _ -> true
    | _ -> false

let isILValueTy =
    function
    | ILType.Value _ -> true
    | _ -> false

let rec stripILModifiedFromTy (ty: ILType) =
    match ty with
    | ILType.Modified(_, _, ty) -> stripILModifiedFromTy ty
    | _ -> ty

let isBuiltInTySpec (ilg: ILGlobals) (tspec: ILTypeSpec) n =
    let tref = tspec.TypeRef
    let scoref = tref.Scope

    tref.Name = n
    && (match scoref with
        | ILScopeRef.Local
        | ILScopeRef.Module _ -> false
        | ILScopeRef.Assembly aref -> ilg.IsPossiblePrimaryAssemblyRef aref
        | ILScopeRef.PrimaryAssembly -> true)

let isILBoxedBuiltInTy ilg (ty: ILType) n =
    isILBoxedTy ty && isBuiltInTySpec ilg ty.TypeSpec n

let isILValueBuiltInTy ilg (ty: ILType) n =
    isILValueTy ty && isBuiltInTySpec ilg ty.TypeSpec n

let isILObjectTy ilg ty = isILBoxedBuiltInTy ilg ty tname_Object

let isILStringTy ilg ty = isILBoxedBuiltInTy ilg ty tname_String

let isILTypedReferenceTy ilg ty =
    isILValueBuiltInTy ilg ty tname_TypedReference

let isILSByteTy ilg ty = isILValueBuiltInTy ilg ty tname_SByte

let isILByteTy ilg ty = isILValueBuiltInTy ilg ty tname_Byte

let isILInt16Ty ilg ty = isILValueBuiltInTy ilg ty tname_Int16

let isILUInt16Ty ilg ty = isILValueBuiltInTy ilg ty tname_UInt16

let isILInt32Ty ilg ty = isILValueBuiltInTy ilg ty tname_Int32

let isILUInt32Ty ilg ty = isILValueBuiltInTy ilg ty tname_UInt32

let isILInt64Ty ilg ty = isILValueBuiltInTy ilg ty tname_Int64

let isILUInt64Ty ilg ty = isILValueBuiltInTy ilg ty tname_UInt64

let isILIntPtrTy ilg ty = isILValueBuiltInTy ilg ty tname_IntPtr

let isILUIntPtrTy ilg ty = isILValueBuiltInTy ilg ty tname_UIntPtr

let isILBoolTy ilg ty = isILValueBuiltInTy ilg ty tname_Bool

let isILCharTy ilg ty = isILValueBuiltInTy ilg ty tname_Char

let isILSingleTy ilg ty = isILValueBuiltInTy ilg ty tname_Single

let isILDoubleTy ilg ty = isILValueBuiltInTy ilg ty tname_Double

// --------------------------------------------------------------------
// Rescoping
// --------------------------------------------------------------------

let rescopeILScopeRef scoref scoref1 =
    match scoref, scoref1 with
    | _, ILScopeRef.Local -> scoref
    | ILScopeRef.Local, _ -> scoref1
    | _, ILScopeRef.Module _ -> scoref
    | ILScopeRef.Module _, _ -> scoref1
    | _ -> scoref1

let rescopeILTypeRef scoref (tref1: ILTypeRef) =
    let scoref1 = tref1.Scope
    let scoref2 = rescopeILScopeRef scoref scoref1

    if scoref1 === scoref2 then
        tref1
    else
        ILTypeRef.Create(scoref2, tref1.Enclosing, tref1.Name)

// ORIGINAL IMPLEMENTATION (too many allocations
//         { tspecTypeRef=rescopeILTypeRef scoref tref
//           tspecInst=rescopeILTypes scoref tinst }
let rec rescopeILTypeSpec scoref (tspec1: ILTypeSpec) =
    let tref1 = tspec1.TypeRef
    let tinst1 = tspec1.GenericArgs
    let tref2 = rescopeILTypeRef scoref tref1

    // avoid reallocation in the common case
    if tref1 === tref2 then
        if isNil tinst1 then
            tspec1
        else
            let tinst2 = rescopeILTypes scoref tinst1

            if tinst1 === tinst2 then
                tspec1
            else
                ILTypeSpec.Create(tref2, tinst2)
    else
        let tinst2 = rescopeILTypes scoref tinst1
        ILTypeSpec.Create(tref2, tinst2)

and rescopeILType scoref ty =
    match ty with
    | ILType.Ptr t -> ILType.Ptr(rescopeILType scoref t)
    | ILType.FunctionPointer t -> ILType.FunctionPointer(rescopeILCallSig scoref t)
    | ILType.Byref t -> ILType.Byref(rescopeILType scoref t)
    | ILType.Boxed cr1 ->
        let cr2 = rescopeILTypeSpec scoref cr1

        if cr1 === cr2 then ty else mkILBoxedType cr2
    | ILType.Array(s, ety1) ->
        let ety2 = rescopeILType scoref ety1

        if ety1 === ety2 then ty else ILType.Array(s, ety2)
    | ILType.Value cr1 ->
        let cr2 = rescopeILTypeSpec scoref cr1

        if cr1 === cr2 then ty else ILType.Value cr2
    | ILType.Modified(b, tref, ty) -> ILType.Modified(b, rescopeILTypeRef scoref tref, rescopeILType scoref ty)
    | x -> x

and rescopeILTypes scoref i =
    if isNil i then i else List.mapq (rescopeILType scoref) i

and rescopeILCallSig scoref csig =
    mkILCallSig (csig.CallingConv, rescopeILTypes scoref csig.ArgTypes, rescopeILType scoref csig.ReturnType)

let rescopeILMethodRef scoref (x: ILMethodRef) =
    {
        mrefParent = rescopeILTypeRef scoref x.DeclaringTypeRef
        mrefCallconv = x.mrefCallconv
        mrefGenericArity = x.mrefGenericArity
        mrefName = x.mrefName
        mrefArgs = rescopeILTypes scoref x.mrefArgs
        mrefReturn = rescopeILType scoref x.mrefReturn
    }

let rescopeILFieldRef scoref x =
    {
        DeclaringTypeRef = rescopeILTypeRef scoref x.DeclaringTypeRef
        Name = x.Name
        Type = rescopeILType scoref x.Type
    }

// --------------------------------------------------------------------
// Instantiate polymorphism in types
// --------------------------------------------------------------------

let rec instILTypeSpecAux numFree inst (tspec: ILTypeSpec) =
    ILTypeSpec.Create(tspec.TypeRef, instILGenericArgsAux numFree inst tspec.GenericArgs)

and instILTypeAux numFree (inst: ILGenericArgs) ty =
    match ty with
    | ILType.Ptr t -> ILType.Ptr(instILTypeAux numFree inst t)
    | ILType.FunctionPointer t -> ILType.FunctionPointer(instILCallSigAux numFree inst t)
    | ILType.Array(a, t) -> ILType.Array(a, instILTypeAux numFree inst t)
    | ILType.Byref t -> ILType.Byref(instILTypeAux numFree inst t)
    | ILType.Boxed cr -> mkILBoxedType (instILTypeSpecAux numFree inst cr)
    | ILType.Value cr -> ILType.Value(instILTypeSpecAux numFree inst cr)
    | ILType.TypeVar v ->
        let v = int v
        let top = inst.Length

        if v < numFree then
            ty
        else if v - numFree >= top then
            ILType.TypeVar(uint16 (v - top))
        else
            List.item (v - numFree) inst
    | x -> x

and instILGenericArgsAux numFree inst i = List.map (instILTypeAux numFree inst) i

and instILCallSigAux numFree inst csig =
    mkILCallSig (csig.CallingConv, List.map (instILTypeAux numFree inst) csig.ArgTypes, instILTypeAux numFree inst csig.ReturnType)

let instILType i t = instILTypeAux 0 i t

// --------------------------------------------------------------------
// MS-IL: Parameters, Return types and Locals
// --------------------------------------------------------------------

let mkILParam (name, ty) : ILParameter =
    {
        Name = name
        Default = None
        Marshal = None
        IsIn = false
        IsOut = false
        IsOptional = false
        Type = ty
        CustomAttrsStored = storeILCustomAttrs emptyILCustomAttrs
        MetadataIndex = NoMetadataIdx
    }

let mkILParamNamed (s, ty) = mkILParam (Some s, ty)

let mkILParamAnon ty = mkILParam (None, ty)

let mkILReturn ty : ILReturn =
    {
        Marshal = None
        Type = ty
        CustomAttrsStored = storeILCustomAttrs emptyILCustomAttrs
        MetadataIndex = NoMetadataIdx
    }

let mkILLocal ty dbgInfo : ILLocal =
    {
        IsPinned = false
        Type = ty
        DebugInfo = dbgInfo
    }

type ILFieldSpec with

    member fr.ActualType =
        let env = fr.DeclaringType.GenericArgs
        instILType env fr.FormalType

// --------------------------------------------------------------------
// Make a method mbody
// --------------------------------------------------------------------

let mkILMethodBody (initlocals, locals, maxstack, code, tag, imports) : ILMethodBody =
    {
        IsZeroInit = initlocals
        MaxStack = maxstack
        NoInlining = false
        AggressiveInlining = false
        Locals = locals
        Code = code
        DebugRange = tag
        DebugImports = imports
    }

let mkMethodBody (zeroinit, locals, maxstack, code, tag, imports) =
    let ilCode = mkILMethodBody (zeroinit, locals, maxstack, code, tag, imports)
    MethodBody.IL(InterruptibleLazy.FromValue ilCode)

// --------------------------------------------------------------------
// Make a constructor
// --------------------------------------------------------------------

let mkILVoidReturn = mkILReturn ILType.Void

let methBodyNotAvailable = notlazy MethodBody.NotAvailable

let methBodyAbstract = notlazy MethodBody.Abstract

let methBodyNative = notlazy MethodBody.Native

let mkILCtor (access, args, impl) =
    ILMethodDef(
        name = ".ctor",
        attributes =
            (convertMemberAccess access
             ||| MethodAttributes.SpecialName
             ||| MethodAttributes.RTSpecialName),
        implAttributes = MethodImplAttributes.Managed,
        callingConv = ILCallingConv.Instance,
        parameters = args,
        ret = mkILVoidReturn,
        body = notlazy impl,
        securityDecls = emptyILSecurityDecls,
        isEntryPoint = false,
        genericParams = mkILEmptyGenericParams,
        customAttrs = emptyILCustomAttrs
    )

// --------------------------------------------------------------------
// Do-nothing ctor, just pass on to monomorphic superclass
// --------------------------------------------------------------------

let mkCallBaseConstructor (ty, args: ILType list) =
    [ mkLdarg0 ]
    @ List.mapi (fun i _ -> mkLdarg (uint16 (i + 1))) args
    @ [ mkNormalCall (mkILCtorMethSpecForTy (ty, [])) ]

let mkNormalStfld fspec = I_stfld(Aligned, Nonvolatile, fspec)

let mkNormalStsfld fspec = I_stsfld(Nonvolatile, fspec)

let mkNormalLdsfld fspec = I_ldsfld(Nonvolatile, fspec)

let mkNormalLdfld fspec = I_ldfld(Aligned, Nonvolatile, fspec)

let mkNormalLdflda fspec = I_ldflda fspec

let mkNormalLdobj dt = I_ldobj(Aligned, Nonvolatile, dt)

let mkNormalStobj dt = I_stobj(Aligned, Nonvolatile, dt)

let mkILNonGenericEmptyCtor (superTy, tag, imports) =
    let ctor = mkCallBaseConstructor (superTy, [])
    let body = mkMethodBody (false, [], 8, nonBranchingInstrsToCode ctor, tag, imports)
    mkILCtor (ILMemberAccess.Public, [], body)

// --------------------------------------------------------------------
// Make a static, top level monomorphic method - very useful for
// creating helper ILMethodDefs for internal use.
// --------------------------------------------------------------------

let mkILStaticMethod (genparams, nm, access, args, ret, impl) =
    ILMethodDef(
        genericParams = genparams,
        name = nm,
        attributes = (convertMemberAccess access ||| MethodAttributes.Static),
        implAttributes = MethodImplAttributes.Managed,
        callingConv = ILCallingConv.Static,
        parameters = args,
        ret = ret,
        securityDecls = emptyILSecurityDecls,
        isEntryPoint = false,
        customAttrs = emptyILCustomAttrs,
        body = notlazy impl
    )

let mkILNonGenericStaticMethod (nm, access, args, ret, impl) =
    mkILStaticMethod (mkILEmptyGenericParams, nm, access, args, ret, impl)

let mkILClassCtor impl =
    ILMethodDef(
        name = ".cctor",
        attributes =
            (MethodAttributes.Private
             ||| MethodAttributes.Static
             ||| MethodAttributes.SpecialName
             ||| MethodAttributes.RTSpecialName),
        implAttributes = MethodImplAttributes.Managed,
        callingConv = ILCallingConv.Static,
        genericParams = mkILEmptyGenericParams,
        parameters = [],
        ret = mkILVoidReturn,
        isEntryPoint = false,
        securityDecls = emptyILSecurityDecls,
        customAttrs = emptyILCustomAttrs,
        body = notlazy impl
    )

let mkILGenericVirtualMethod (nm, callconv: ILCallingConv, access, genparams, actual_args, actual_ret, impl) =
    let attributes =
        convertMemberAccess access
        ||| MethodAttributes.CheckAccessOnOverride
        ||| (match impl with
             | MethodBody.Abstract -> MethodAttributes.Abstract ||| MethodAttributes.Virtual
             | _ -> MethodAttributes.Virtual)
        ||| (if callconv.IsInstance then
                 enum 0
             else
                 MethodAttributes.Static)

    ILMethodDef(
        name = nm,
        attributes = attributes,
        implAttributes = MethodImplAttributes.Managed,
        genericParams = genparams,
        callingConv = callconv,
        parameters = actual_args,
        ret = actual_ret,
        isEntryPoint = false,
        securityDecls = emptyILSecurityDecls,
        customAttrs = emptyILCustomAttrs,
        body = notlazy impl
    )

let mkILNonGenericVirtualMethod (nm, callconv, access, args, ret, impl) =
    mkILGenericVirtualMethod (nm, callconv, access, mkILEmptyGenericParams, args, ret, impl)

let mkILNonGenericVirtualInstanceMethod (nm, access, args, ret, impl) =
    mkILNonGenericVirtualMethod (nm, ILCallingConv.Instance, access, args, ret, impl)

let mkILGenericNonVirtualMethod (nm, access, genparams, actual_args, actual_ret, impl) =
    ILMethodDef(
        name = nm,
        attributes = (convertMemberAccess access ||| MethodAttributes.HideBySig),
        implAttributes = MethodImplAttributes.Managed,
        genericParams = genparams,
        callingConv = ILCallingConv.Instance,
        parameters = actual_args,
        ret = actual_ret,
        isEntryPoint = false,
        securityDecls = emptyILSecurityDecls,
        customAttrs = emptyILCustomAttrs,
        body = notlazy impl
    )

let mkILNonGenericInstanceMethod (nm, access, args, ret, impl) =
    mkILGenericNonVirtualMethod (nm, access, mkILEmptyGenericParams, args, ret, impl)

// --------------------------------------------------------------------
// Add some code to the end of the .cctor for a type. Create a .cctor
// if one doesn't exist already.
// --------------------------------------------------------------------

let ilmbody_code2code f (il: ILMethodBody) = { il with Code = f il.Code }

let mdef_code2code f (md: ILMethodDef) =
    let il =
        match md.Body with
        | MethodBody.IL il -> il
        | _ -> failwith "mdef_code2code - method not IL"

    let ilCode = ilmbody_code2code f il.Value
    let b = MethodBody.IL(notlazy ilCode)
    md.With(body = notlazy b)

let appendInstrsToCode (instrs: ILInstr list) (c2: ILCode) =
    let instrs = Array.ofList instrs

    match
        c2.Instrs
        |> Array.tryFindIndexBack (fun instr ->
            match instr with
            | I_ret -> true
            | _ -> false)
    with
    | Some 0 ->
        { c2 with
            Instrs = Array.concat [| instrs; c2.Instrs |]
        }
    | Some index ->
        { c2 with
            Instrs = Array.concat [| c2.Instrs[.. index - 1]; instrs; c2.Instrs[index..] |]
        }
    | None ->
        { c2 with
            Instrs = Array.append c2.Instrs instrs
        }

let prependInstrsToCode (instrs: ILInstr list) (c2: ILCode) =
    let instrs = Array.ofList instrs
    let n = instrs.Length

    match c2.Instrs[0] with
    // If there is a sequence point as the first instruction then keep it at the front
    | I_seqpoint _ as i0 ->
        let labels =
            let dict = Dictionary.newWithSize (c2.Labels.Count * 2) // Decrease chance of collisions by oversizing the hashtable

            for kvp in c2.Labels do
                dict.Add(kvp.Key, (if kvp.Value = 0 then 0 else kvp.Value + n))

            dict

        { c2 with
            Labels = labels
            Instrs = Array.concat [| [| i0 |]; instrs; c2.Instrs[1..] |]
        }
    | _ ->
        let labels =
            let dict = Dictionary.newWithSize (c2.Labels.Count * 2) // Decrease chance of collisions by oversizing the hashtable

            for kvp in c2.Labels do
                dict.Add(kvp.Key, kvp.Value + n)

            dict

        { c2 with
            Labels = labels
            Instrs = Array.append instrs c2.Instrs
        }

let appendInstrsToMethod newCode md =
    mdef_code2code (appendInstrsToCode newCode) md

let prependInstrsToMethod newCode md =
    mdef_code2code (prependInstrsToCode newCode) md

// Creates cctor if needed
let cdef_cctorCode2CodeOrCreate tag imports f (cd: ILTypeDef) =
    let mdefs = cd.Methods

    let cctor, renamedCctors =
        match mdefs.FindByName ".cctor" with
        | [ mdef ] -> mdef, []
        | [] ->
            let body = mkMethodBody (false, [], 1, nonBranchingInstrsToCode [], tag, imports)
            mkILClassCtor body, []
        | multipleCctors ->
            // Handle multiple .cctor methods by renaming them and creating a new .cctor that calls them
            // This resolves the "duplicate entry '.cctor' in method table" error (FS2014)
            let renamedCctors =
                multipleCctors
                |> List.mapi (fun i mdef ->
                    let newName = sprintf "cctor_renamed_%d" i
                    mdef.With(name = newName))

            // Create call instructions for each renamed .cctor
            // Use a simple self-referencing type
            let currentTypeRef = mkILTyRef (ILScopeRef.Local, cd.Name)
            let currentType = mkILNonGenericBoxedTy currentTypeRef

            let callInstrs =
                renamedCctors
                |> List.map (fun mdef ->
                    let mspec =
                        mkILNonGenericStaticMethSpecInTy (currentType, mdef.Name, [], ILType.Void)

                    mkNormalCall mspec)

            // Create new .cctor that calls all renamed methods
            let newCctorInstrs = callInstrs @ [ I_ret ]

            let newCctorBody =
                mkMethodBody (false, [], 8, nonBranchingInstrsToCode newCctorInstrs, tag, imports)

            let newCctor = mkILClassCtor newCctorBody

            newCctor, renamedCctors

    let methods =
        ILMethodDefs(fun () ->
            [|
                yield f cctor
                yield! renamedCctors
                for md in mdefs do
                    if md.Name <> ".cctor" then
                        yield md
            |])

    cd.With(methods = methods)

let mkRefToILMethod (tref, md: ILMethodDef) =
    mkILMethRef (tref, md.CallingConv, md.Name, md.GenericParams.Length, md.ParameterTypes, md.Return.Type)

let mkRefToILField (tref, fdef: ILFieldDef) =
    mkILFieldRef (tref, fdef.Name, fdef.FieldType)

let mkRefForILMethod scope (tdefs, tdef) mdef =
    mkRefToILMethod (mkRefForNestedILTypeDef scope (tdefs, tdef), mdef)

let mkRefForILField scope (tdefs, tdef) (fdef: ILFieldDef) =
    mkILFieldRef (mkRefForNestedILTypeDef scope (tdefs, tdef), fdef.Name, fdef.FieldType)

// Creates cctor if needed
let prependInstrsToClassCtor instrs tag imports cd =
    cdef_cctorCode2CodeOrCreate tag imports (prependInstrsToMethod instrs) cd

let mkILField (isStatic, nm, ty, init: ILFieldInit option, at: byte[] option, access, isLiteral) =
    ILFieldDef(
        name = nm,
        fieldType = ty,
        attributes =
            (convertFieldAccess access
             ||| (if isStatic then FieldAttributes.Static else enum 0)
             ||| (if isLiteral then FieldAttributes.Literal else enum 0)
             ||| (if init.IsSome then FieldAttributes.HasDefault else enum 0)
             ||| (if at.IsSome then FieldAttributes.HasFieldRVA else enum 0)),
        literalValue = init,
        data = at,
        offset = None,
        marshal = None,
        customAttrs = emptyILCustomAttrs
    )

let mkILInstanceField (nm, ty, init, access) =
    mkILField (false, nm, ty, init, None, access, false)

let mkILStaticField (nm, ty, init, at, access) =
    mkILField (true, nm, ty, init, at, access, false)

let mkILStaticLiteralField (nm, ty, init, at, access) =
    mkILField (true, nm, ty, Some init, at, access, true)

let mkILLiteralField (nm, ty, init, at, access) =
    mkILField (true, nm, ty, Some init, at, access, true)

// --------------------------------------------------------------------
// Scopes for allocating new temporary variables.
// --------------------------------------------------------------------

type ILLocalsAllocator(preAlloc: int) =
    let newLocals = ResizeArray<ILLocal>()

    member tmps.AllocLocal loc =
        let locn = uint16 (preAlloc + newLocals.Count)
        newLocals.Add loc
        locn

    member tmps.Close() = ResizeArray.toList newLocals

let mkILFieldsLazy l =
    ILFields(LazyOrderedMultiMap((fun (fdef: ILFieldDef) -> fdef.Name), l))

let mkILFields l = mkILFieldsLazy (notlazy l)

let emptyILFields = mkILFields []

let mkILEventsLazy l =
    ILEvents(LazyOrderedMultiMap((fun (edef: ILEventDef) -> edef.Name), l))

let mkILEvents l = mkILEventsLazy (notlazy l)

let emptyILEvents = mkILEvents []

let mkILPropertiesLazy l =
    ILProperties(LazyOrderedMultiMap((fun (pdef: ILPropertyDef) -> pdef.Name), l))

let mkILProperties l = mkILPropertiesLazy (notlazy l)

let emptyILProperties = mkILProperties []

let addExportedTypeToTable (y: ILExportedTypeOrForwarder) tab = Map.add y.Name y tab

let mkILExportedTypes l =
    ILExportedTypesAndForwarders(notlazy (List.foldBack addExportedTypeToTable l Map.empty))

let mkILExportedTypesLazy (l: Lazy<_>) =
    ILExportedTypesAndForwarders(InterruptibleLazy(fun _ -> List.foldBack addExportedTypeToTable (l.Force()) Map.empty))

let addNestedExportedTypeToTable (y: ILNestedExportedType) tab = Map.add y.Name y tab

let mkTypeForwarder scopeRef name nested customAttrs access =
    {
        ScopeRef = scopeRef
        Name = name
        Attributes = enum<TypeAttributes> 0x00200000 ||| convertTypeAccessFlags access
        Nested = nested
        CustomAttrsStored = storeILCustomAttrs customAttrs
        MetadataIndex = NoMetadataIdx
    }

let mkILNestedExportedTypes l =
    ILNestedExportedTypes(notlazy (List.foldBack addNestedExportedTypeToTable l Map.empty))

let mkILNestedExportedTypesLazy (l: Lazy<_>) =
    ILNestedExportedTypes(InterruptibleLazy(fun _ -> List.foldBack addNestedExportedTypeToTable (l.Force()) Map.empty))

let mkILResources l = ILResources l
let emptyILResources = ILResources []

let addMethodImplToTable y tab =
    let key = (y.Overrides.MethodRef.Name, y.Overrides.MethodRef.ArgTypes.Length)
    let prev = Map.tryFindMulti key tab
    Map.add key (y :: prev) tab

let mkILMethodImpls l =
    ILMethodImpls(notlazy (List.foldBack addMethodImplToTable l Map.empty))

let mkILMethodImplsLazy l =
    ILMethodImpls(InterruptibleLazy(fun _ -> List.foldBack addMethodImplToTable (Lazy.force l) Map.empty))

let emptyILMethodImpls = mkILMethodImpls []

/// Make a constructor that simply takes its arguments and stuffs
/// them in fields. preblock is how to call the superclass constructor....
let mkILStorageCtorWithParamNames (preblock: ILInstr list, ty, extraParams, flds, access, tag, imports) =
    let code =
        [
            match tag with
            | Some x -> I_seqpoint x
            | None -> ()
            yield! preblock
            for n, (_pnm, nm, fieldTy, _attrs) in List.indexed flds do
                mkLdarg0
                mkLdarg (uint16 (n + 1))
                mkNormalStfld (mkILFieldSpecInTy (ty, nm, fieldTy))
        ]

    let body = mkMethodBody (false, [], 2, nonBranchingInstrsToCode code, tag, imports)

    let fieldParams =
        [
            for pnm, _, ty, attrs in flds do
                let ilParam = mkILParamNamed (pnm, ty)

                let ilParam =
                    match attrs with
                    | [] -> ilParam
                    | attrs ->
                        { ilParam with
                            CustomAttrsStored = storeILCustomAttrs (mkILCustomAttrs attrs)
                        }

                yield ilParam
        ]

    mkILCtor (access, fieldParams @ extraParams, body)

let mkILSimpleStorageCtorWithParamNames (baseTySpec, ty, extraParams, flds, access, tag, imports) =
    let preblock =
        match baseTySpec with
        | None -> []
        | Some tspec -> [ mkLdarg0; mkNormalCall (mkILCtorMethSpecForTy (mkILBoxedType tspec, [])) ]

    mkILStorageCtorWithParamNames (preblock, ty, extraParams, flds, access, tag, imports)

let addParamNames flds =
    flds |> List.map (fun (nm, ty, attrs) -> (nm, nm, ty, attrs))

let mkILSimpleStorageCtor (baseTySpec, ty, extraParams, flds, access, tag, imports) =
    mkILSimpleStorageCtorWithParamNames (baseTySpec, ty, extraParams, addParamNames flds, access, tag, imports)

let mkILStorageCtor (preblock, ty, flds, access, tag, imports) =
    mkILStorageCtorWithParamNames (preblock, ty, [], addParamNames flds, access, tag, imports)

let mkILGenericClass (nm, access, genparams, extends, impls, methods, fields, nestedTypes, props, events, attrs, init) =
    let attributes =
        convertTypeAccessFlags access
        ||| TypeAttributes.AutoLayout
        ||| TypeAttributes.Class
        ||| (match init with
             | ILTypeInit.BeforeField -> TypeAttributes.BeforeFieldInit
             | _ -> enum 0)
        ||| TypeAttributes.AnsiClass

    ILTypeDef(
        name = nm,
        attributes = attributes,
        genericParams = genparams,
        implements = impls,
        layout = ILTypeDefLayout.Auto,
        extends = Some extends,
        methods = methods,
        fields = fields,
        nestedTypes = nestedTypes,
        customAttrs = storeILCustomAttrs attrs,
        methodImpls = emptyILMethodImpls,
        properties = props,
        events = events,
        securityDecls = emptyILSecurityDecls
    )

let mkRawDataValueTypeDef (iltyp_ValueType: ILType) (nm, size, pack) =
    ILTypeDef(
        name = nm,
        genericParams = [],
        attributes =
            (TypeAttributes.NotPublic
             ||| TypeAttributes.Sealed
             ||| TypeAttributes.ExplicitLayout
             ||| TypeAttributes.BeforeFieldInit
             ||| TypeAttributes.AnsiClass),
        implements = [],
        extends = Some iltyp_ValueType,
        layout = ILTypeDefLayout.Explicit { Size = Some size; Pack = Some pack },
        methods = emptyILMethods,
        fields = emptyILFields,
        nestedTypes = emptyILTypeDefs,
        customAttrs = emptyILCustomAttrsStored,
        methodImpls = emptyILMethodImpls,
        properties = emptyILProperties,
        events = emptyILEvents,
        securityDecls = emptyILSecurityDecls
    )

let mkILSimpleClass (ilg: ILGlobals) (nm, access, methods, fields, nestedTypes, props, events, attrs, init) =
    mkILGenericClass (nm, access, mkILEmptyGenericParams, ilg.typ_Object, [], methods, fields, nestedTypes, props, events, attrs, init)

let mkILTypeDefForGlobalFunctions ilg (methods, fields) =
    mkILSimpleClass
        ilg
        (typeNameForGlobalFunctions,
         ILTypeDefAccess.Public,
         methods,
         fields,
         emptyILTypeDefs,
         emptyILProperties,
         emptyILEvents,
         emptyILCustomAttrs,
         ILTypeInit.BeforeField)

let destTypeDefsWithGlobalFunctionsFirst ilg (tdefs: ILTypeDefs) =
    let l = tdefs.AsList()

    let top, nontop =
        l |> List.partition (fun td -> td.Name = typeNameForGlobalFunctions)

    let top2 =
        if isNil top then
            [ mkILTypeDefForGlobalFunctions ilg (emptyILMethods, emptyILFields) ]
        else
            top

    top2 @ nontop

let mkILSimpleModule
    assemblyName
    moduleName
    dll
    subsystemVersion
    useHighEntropyVA
    tdefs
    hashalg
    locale
    flags
    exportedTypes
    metadataVersion
    =
    let manifest =
        {
            Name = assemblyName
            AuxModuleHashAlgorithm =
                match hashalg with
                | Some alg -> alg
                | _ -> 0x8004 // SHA1
            SecurityDeclsStored = emptyILSecurityDeclsStored
            PublicKey = None
            Version = None
            Locale = locale
            CustomAttrsStored = storeILCustomAttrs emptyILCustomAttrs
            AssemblyLongevity = ILAssemblyLongevity.Unspecified
            DisableJitOptimizations = 0 <> (flags &&& 0x4000)
            JitTracking = (0 <> (flags &&& 0x8000)) // always turn these on
            IgnoreSymbolStoreSequencePoints = false
            Retargetable = (0 <> (flags &&& 0x100))
            ExportedTypes = exportedTypes
            EntrypointElsewhere = None
            MetadataIndex = NoMetadataIdx
        }

    {
        Manifest = Some manifest
        CustomAttrsStored = storeILCustomAttrs emptyILCustomAttrs
        Name = moduleName
        NativeResources = []
        TypeDefs = tdefs
        SubsystemVersion = subsystemVersion
        UseHighEntropyVA = useHighEntropyVA
        SubSystemFlags = defaultSubSystem
        IsDLL = dll
        IsILOnly = true
        Platform = None
        StackReserveSize = None
        Is32Bit = false
        Is32BitPreferred = false
        Is64Bit = false
        PhysicalAlignment = defaultPhysAlignment
        VirtualAlignment = defaultVirtAlignment
        ImageBase = defaultImageBase
        MetadataVersion = metadataVersion
        Resources = mkILResources []
        MetadataIndex = NoMetadataIdx
    }

//-----------------------------------------------------------------------
// [instructions_to_code] makes the basic block structure of code from
// a primitive array of instructions. We
// do this be iterating over the instructions, pushing new basic blocks
// every time we encounter an address that has been recorded
// [bbstartToCodeLabelMap].
//-----------------------------------------------------------------------

// REVIEW: this function shows up on performance traces. If we eliminated the last ILX->IL rewrites from the
// F# compiler we could get rid of this structured code representation from Abstract IL altogether and
// never convert F# code into this form.
let buildILCode (_methName: string) lab2pc instrs tryspecs localspecs : ILCode =
    {
        Labels = lab2pc
        Instrs = instrs
        Exceptions = tryspecs
        Locals = localspecs
    }

// --------------------------------------------------------------------
// Detecting Delegates
// --------------------------------------------------------------------

let mkILDelegateMethods access (ilg: ILGlobals) (iltyp_AsyncCallback, iltyp_IAsyncResult) (params_, rtv: ILReturn) =
    let retTy = rtv.Type

    let one nm args ret =
        let mdef =
            mkILNonGenericVirtualInstanceMethod (nm, access, args, mkILReturn ret, MethodBody.Abstract)

        mdef.WithAbstract(false).WithHideBySig(true).WithRuntime(true)

    let ctor =
        mkILCtor (
            access,
            [
                mkILParamNamed ("object", ilg.typ_Object)
                mkILParamNamed ("method", ilg.typ_IntPtr)
            ],
            MethodBody.Abstract
        )

    let ctor = ctor.WithRuntime(true).WithHideBySig(true)

    [
        ctor
        one "Invoke" params_ retTy
        one
            "BeginInvoke"
            (params_
             @ [
                 mkILParamNamed ("callback", iltyp_AsyncCallback)
                 mkILParamNamed ("objects", ilg.typ_Object)
             ])
            iltyp_IAsyncResult
        one "EndInvoke" [ mkILParamNamed ("result", iltyp_IAsyncResult) ] retTy
    ]

let mkCtorMethSpecForDelegate (ilg: ILGlobals) (ty: ILType, useUIntPtr) =
    let scoref = ty.TypeRef.Scope

    let argTys =
        [
            rescopeILType scoref ilg.typ_Object
            rescopeILType scoref (if useUIntPtr then ilg.typ_UIntPtr else ilg.typ_IntPtr)
        ]

    mkILInstanceMethSpecInTy (ty, ".ctor", argTys, ILType.Void, emptyILGenericArgsList)

type ILEnumInfo =
    {
        enumValues: (string * ILFieldInit) list
        enumType: ILType
    }

let getTyOfILEnumInfo info = info.enumType

let computeILEnumInfo (mdName, mdFields: ILFieldDefs) =
    match (List.partition (fun (fd: ILFieldDef) -> fd.IsStatic) (mdFields.AsList())) with
    | staticFields, [ vfd ] ->
        {
            enumType = vfd.FieldType
            enumValues =
                staticFields
                |> List.map (fun fd ->
                    (fd.Name,
                     match fd.LiteralValue with
                     | Some i -> i
                     | None ->
                         failwith (
                             "computeILEnumInfo: badly formed enum "
                             + mdName
                             + ": static field does not have an default value"
                         )))
        }
    | _, [] -> failwith ("computeILEnumInfo: badly formed enum " + mdName + ": no non-static field found")
    | _, _ ->
        failwith (
            "computeILEnumInfo: badly formed enum "
            + mdName
            + ": more than one non-static field found"
        )

//---------------------------------------------------------------------
// Primitives to help read signatures. These do not use the file cursor, but
// pass around an int index
//---------------------------------------------------------------------

let sigptr_get_byte bytes sigptr = Bytes.get bytes sigptr, sigptr + 1

let sigptr_get_u8 bytes sigptr =
    let b0, sigptr = sigptr_get_byte bytes sigptr
    byte b0, sigptr

let sigptr_get_i8 bytes sigptr =
    let i, sigptr = sigptr_get_u8 bytes sigptr
    sbyte i, sigptr

let sigptr_get_u16 bytes sigptr =
    let b0, sigptr = sigptr_get_byte bytes sigptr
    let b1, sigptr = sigptr_get_byte bytes sigptr
    uint16 (b0 ||| (b1 <<< 8)), sigptr

let sigptr_get_i16 bytes sigptr =
    let u, sigptr = sigptr_get_u16 bytes sigptr
    int16 u, sigptr

let sigptr_get_i32 bytes sigptr =
    let b0, sigptr = sigptr_get_byte bytes sigptr
    let b1, sigptr = sigptr_get_byte bytes sigptr
    let b2, sigptr = sigptr_get_byte bytes sigptr
    let b3, sigptr = sigptr_get_byte bytes sigptr
    b0 ||| (b1 <<< 8) ||| (b2 <<< 16) ||| (b3 <<< 24), sigptr

let sigptr_get_u32 bytes sigptr =
    let u, sigptr = sigptr_get_i32 bytes sigptr
    uint32 u, sigptr

let sigptr_get_i64 bytes sigptr =
    let b0, sigptr = sigptr_get_byte bytes sigptr
    let b1, sigptr = sigptr_get_byte bytes sigptr
    let b2, sigptr = sigptr_get_byte bytes sigptr
    let b3, sigptr = sigptr_get_byte bytes sigptr
    let b4, sigptr = sigptr_get_byte bytes sigptr
    let b5, sigptr = sigptr_get_byte bytes sigptr
    let b6, sigptr = sigptr_get_byte bytes sigptr
    let b7, sigptr = sigptr_get_byte bytes sigptr

    int64 b0
    ||| (int64 b1 <<< 8)
    ||| (int64 b2 <<< 16)
    ||| (int64 b3 <<< 24)
    ||| (int64 b4 <<< 32)
    ||| (int64 b5 <<< 40)
    ||| (int64 b6 <<< 48)
    ||| (int64 b7 <<< 56),
    sigptr

let sigptr_get_u64 bytes sigptr =
    let u, sigptr = sigptr_get_i64 bytes sigptr
    uint64 u, sigptr

let float32OfBits (x: int32) =
    BitConverter.ToSingle(BitConverter.GetBytes x, 0)

let floatOfBits (x: int64) = BitConverter.Int64BitsToDouble x

let sigptr_get_ieee32 bytes sigptr =
    let u, sigptr = sigptr_get_i32 bytes sigptr
    float32OfBits u, sigptr

let sigptr_get_ieee64 bytes sigptr =
    let u, sigptr = sigptr_get_i64 bytes sigptr
    floatOfBits u, sigptr

let sigptr_get_intarray n (bytes: byte[]) sigptr =
    let res = Bytes.zeroCreate n

    for i = 0 to n - 1 do
        res[i] <- bytes[sigptr + i]

    res, sigptr + n

let sigptr_get_string n bytes sigptr =
    let intarray, sigptr = sigptr_get_intarray n bytes sigptr
    Encoding.UTF8.GetString(intarray, 0, intarray.Length), sigptr

let sigptr_get_z_i32 bytes sigptr =
    let b0, sigptr = sigptr_get_byte bytes sigptr

    if b0 <= 0x7F then
        b0, sigptr
    elif b0 <= 0xbf then
        let b0 = b0 &&& 0x7f
        let b1, sigptr = sigptr_get_byte bytes sigptr
        (b0 <<< 8) ||| b1, sigptr
    else
        let b0 = b0 &&& 0x3f
        let b1, sigptr = sigptr_get_byte bytes sigptr
        let b2, sigptr = sigptr_get_byte bytes sigptr
        let b3, sigptr = sigptr_get_byte bytes sigptr
        (b0 <<< 24) ||| (b1 <<< 16) ||| (b2 <<< 8) ||| b3, sigptr

let sigptr_get_serstring bytes sigptr =
    let len, sigptr = sigptr_get_z_i32 bytes sigptr
    sigptr_get_string len bytes sigptr

let sigptr_get_serstring_possibly_null bytes sigptr =
    let b0, new_sigptr = sigptr_get_byte bytes sigptr

    if b0 = 0xFF then // null case
        None, new_sigptr
    else // throw away new_sigptr, getting length & text advance
        let len, sigptr = sigptr_get_z_i32 bytes sigptr
        let s, sigptr = sigptr_get_string len bytes sigptr
        Some s, sigptr

//---------------------------------------------------------------------
// Get the public key token from the public key.
//---------------------------------------------------------------------

let mkRefToILAssembly (m: ILAssemblyManifest) =
    ILAssemblyRef.Create(
        m.Name,
        None,
        (match m.PublicKey with
         | Some k -> Some(PublicKey.KeyAsToken k)
         | None -> None),
        m.Retargetable,
        m.Version,
        m.Locale
    )

let z_unsigned_int n =
    if n >= 0 && n <= 0x7F then
        [| byte n |]
    elif n >= 0x80 && n <= 0x3FFF then
        [| byte (0x80 ||| (n >>>& 8)); byte (n &&& 0xFF) |]
    else
        [|
            byte (0xc0 ||| (n >>>& 24))
            byte ((n >>>& 16) &&& 0xFF)
            byte ((n >>>& 8) &&& 0xFF)
            byte (n &&& 0xFF)
        |]

let string_as_utf8_bytes (s: string) = Encoding.UTF8.GetBytes s

(* Little-endian encoding of int64 *)
let dw7 n = byte ((n >>> 56) &&& 0xFFL)

let dw6 n = byte ((n >>> 48) &&& 0xFFL)

let dw5 n = byte ((n >>> 40) &&& 0xFFL)

let dw4 n = byte ((n >>> 32) &&& 0xFFL)

let dw3 n = byte ((n >>> 24) &&& 0xFFL)

let dw2 n = byte ((n >>> 16) &&& 0xFFL)

let dw1 n = byte ((n >>> 8) &&& 0xFFL)

let dw0 n = byte (n &&& 0xFFL)

let u8AsBytes (i: byte) = [| i |]

let u16AsBytes x =
    let n = (int x) in [| byte (b0 n); byte (b1 n) |]

let i32AsBytes i =
    [| byte (b0 i); byte (b1 i); byte (b2 i); byte (b3 i) |]

let i64AsBytes i =
    [| dw0 i; dw1 i; dw2 i; dw3 i; dw4 i; dw5 i; dw6 i; dw7 i |]

let i8AsBytes (i: sbyte) = u8AsBytes (byte i)

let i16AsBytes (i: int16) = u16AsBytes (uint16 i)

let u32AsBytes (i: uint32) = i32AsBytes (int32 i)

let u64AsBytes (i: uint64) = i64AsBytes (int64 i)

let bitsOfSingle (x: float32) =
    BitConverter.ToInt32(BitConverter.GetBytes x, 0)

let bitsOfDouble (x: float) = BitConverter.DoubleToInt64Bits x

let ieee32AsBytes i = i32AsBytes (bitsOfSingle i)

let ieee64AsBytes i = i64AsBytes (bitsOfDouble i)

let et_BOOLEAN = 0x02uy
let et_CHAR = 0x03uy
let et_I1 = 0x04uy
let et_U1 = 0x05uy
let et_I2 = 0x06uy
let et_U2 = 0x07uy
let et_I4 = 0x08uy
let et_U4 = 0x09uy
let et_I8 = 0x0Auy
let et_U8 = 0x0Buy
let et_R4 = 0x0Cuy
let et_R8 = 0x0Duy
let et_STRING = 0x0Euy
let et_OBJECT = 0x1Cuy
let et_SZARRAY = 0x1Duy

let formatILVersion (version: ILVersionInfo) =
    sprintf "%d.%d.%d.%d" (int version.Major) (int version.Minor) (int version.Build) (int version.Revision)

let encodeCustomAttrString s =
    let arr = string_as_utf8_bytes s
    Array.append (z_unsigned_int arr.Length) arr

let rec encodeCustomAttrElemType x =
    match x with
    | ILType.Value tspec when tspec.Name = tname_SByte -> [| et_I1 |]
    | ILType.Value tspec when tspec.Name = tname_Byte -> [| et_U1 |]
    | ILType.Value tspec when tspec.Name = tname_Int16 -> [| et_I2 |]
    | ILType.Value tspec when tspec.Name = tname_UInt16 -> [| et_U2 |]
    | ILType.Value tspec when tspec.Name = tname_Int32 -> [| et_I4 |]
    | ILType.Value tspec when tspec.Name = tname_UInt32 -> [| et_U4 |]
    | ILType.Value tspec when tspec.Name = tname_Int64 -> [| et_I8 |]
    | ILType.Value tspec when tspec.Name = tname_UInt64 -> [| et_U8 |]
    | ILType.Value tspec when tspec.Name = tname_Double -> [| et_R8 |]
    | ILType.Value tspec when tspec.Name = tname_Single -> [| et_R4 |]
    | ILType.Value tspec when tspec.Name = tname_Char -> [| et_CHAR |]
    | ILType.Value tspec when tspec.Name = tname_Bool -> [| et_BOOLEAN |]
    | ILType.Boxed tspec when tspec.Name = tname_String -> [| et_STRING |]
    | ILType.Boxed tspec when tspec.Name = tname_Object -> [| 0x51uy |]
    | ILType.Boxed tspec when tspec.Name = tname_Type -> [| 0x50uy |]
    | ILType.Value tspec -> Array.append [| 0x55uy |] (encodeCustomAttrString tspec.TypeRef.QualifiedName)
    | ILType.Array(shape, elemType) when shape = ILArrayShape.SingleDimensional ->
        Array.append [| et_SZARRAY |] (encodeCustomAttrElemType elemType)
    | _ -> failwith "encodeCustomAttrElemType: unrecognized custom element type"

/// Given a custom attribute element, work out the type of the .NET argument for that element.
let rec encodeCustomAttrElemTypeForObject x =
    match x with
    | ILAttribElem.String _ -> [| et_STRING |]
    | ILAttribElem.Bool _ -> [| et_BOOLEAN |]
    | ILAttribElem.Char _ -> [| et_CHAR |]
    | ILAttribElem.SByte _ -> [| et_I1 |]
    | ILAttribElem.Int16 _ -> [| et_I2 |]
    | ILAttribElem.Int32 _ -> [| et_I4 |]
    | ILAttribElem.Int64 _ -> [| et_I8 |]
    | ILAttribElem.Byte _ -> [| et_U1 |]
    | ILAttribElem.UInt16 _ -> [| et_U2 |]
    | ILAttribElem.UInt32 _ -> [| et_U4 |]
    | ILAttribElem.UInt64 _ -> [| et_U8 |]
    | ILAttribElem.Type _ -> [| 0x50uy |]
    | ILAttribElem.TypeRef _ -> [| 0x50uy |]
    | ILAttribElem.Null -> [| et_STRING |] // yes, the 0xe prefix is used when passing a "null" to a property or argument of type "object" here
    | ILAttribElem.Single _ -> [| et_R4 |]
    | ILAttribElem.Double _ -> [| et_R8 |]
    | ILAttribElem.Array(elemTy, _) -> [| yield et_SZARRAY; yield! encodeCustomAttrElemType elemTy |]

let tspan = TimeSpan(DateTime.UtcNow.Ticks - DateTime(2000, 1, 1).Ticks)

let parseILVersion (vstr: string) =
    // matches "v1.2.3.4" or "1.2.3.4". Note, if numbers are missing, returns -1 (not 0).
    let mutable vstr = vstr.TrimStart [| 'v' |]
    // if the version string contains wildcards, replace them
    let versionComponents = vstr.Split [| '.' |]

    // account for wildcards
    if versionComponents.Length > 2 then
        let defaultBuild = uint16 tspan.Days % UInt16.MaxValue - 1us

        let defaultRevision =
            uint16 (DateTime.UtcNow.TimeOfDay.TotalSeconds / 2.0) % UInt16.MaxValue - 1us

        if versionComponents[2] = "*" then
            if versionComponents.Length > 3 then
                failwith "Invalid version format"
            else
                // set the build number to the number of days since Jan 1, 2000
                versionComponents[2] <- defaultBuild.ToString()
                // Set the revision number to number of seconds today / 2
                vstr <- String.Join(".", versionComponents) + "." + defaultRevision.ToString()
        elif versionComponents.Length > 3 && versionComponents[3] = "*" then
            // Set the revision number to number of seconds today / 2
            versionComponents[3] <- defaultRevision.ToString()
            vstr <- String.Join(".", versionComponents)

#if FABLE_COMPILER
    let parts = vstr.Split([|'.'|])
    let versions = Array.append (Array.map uint16 parts) [|0us;0us;0us;0us|]
    ILVersionInfo (versions.[0], versions.[1], versions.[2], versions.[3])
#else
    let version = Version vstr
    let zero32 n = if n < 0 then 0us else uint16 n
    // since the minor revision will be -1 if none is specified, we need to truncate to 0 to not break existing code
    let minorRevision =
        if version.Revision = -1 then
            0us
        else
            uint16 version.MinorRevision

    ILVersionInfo(zero32 version.Major, zero32 version.Minor, zero32 version.Build, minorRevision)
#endif

let compareILVersions (version1: ILVersionInfo) (version2: ILVersionInfo) =
    let c = compare version1.Major version2.Major

    if c <> 0 then
        c
    else
        let c = compare version1.Minor version2.Minor

        if c <> 0 then
            c
        else
            let c = compare version1.Build version2.Build

            if c <> 0 then
                c
            else
                let c = compare version1.Revision version2.Revision
                if c <> 0 then c else 0

let DummyFSharpCoreScopeRef =
    let asmRef =
        // The exact public key token and version used here don't actually matter, or shouldn't.
        ILAssemblyRef.Create(
            "FSharp.Core",
            None,
            Some(PublicKeyToken(Bytes.ofInt32Array [| 0xb0; 0x3f; 0x5f; 0x7f; 0x11; 0xd5; 0x0a; 0x3a |])),
            false,
            Some(parseILVersion "0.0.0.0"),
            None
        )

    ILScopeRef.Assembly asmRef

let PrimaryAssemblyILGlobals =
    mkILGlobals (ILScopeRef.PrimaryAssembly, [], DummyFSharpCoreScopeRef)

let rec decodeCustomAttrElemType bytes sigptr x =
    match x with
    | x when x = et_I1 -> PrimaryAssemblyILGlobals.typ_SByte, sigptr
    | x when x = et_U1 -> PrimaryAssemblyILGlobals.typ_Byte, sigptr
    | x when x = et_I2 -> PrimaryAssemblyILGlobals.typ_Int16, sigptr
    | x when x = et_U2 -> PrimaryAssemblyILGlobals.typ_UInt16, sigptr
    | x when x = et_I4 -> PrimaryAssemblyILGlobals.typ_Int32, sigptr
    | x when x = et_U4 -> PrimaryAssemblyILGlobals.typ_UInt32, sigptr
    | x when x = et_I8 -> PrimaryAssemblyILGlobals.typ_Int64, sigptr
    | x when x = et_U8 -> PrimaryAssemblyILGlobals.typ_UInt64, sigptr
    | x when x = et_R8 -> PrimaryAssemblyILGlobals.typ_Double, sigptr
    | x when x = et_R4 -> PrimaryAssemblyILGlobals.typ_Single, sigptr
    | x when x = et_CHAR -> PrimaryAssemblyILGlobals.typ_Char, sigptr
    | x when x = et_BOOLEAN -> PrimaryAssemblyILGlobals.typ_Bool, sigptr
    | x when x = et_STRING -> PrimaryAssemblyILGlobals.typ_String, sigptr
    | x when x = et_OBJECT -> PrimaryAssemblyILGlobals.typ_Object, sigptr
    | x when x = et_SZARRAY ->
        let et, sigptr = sigptr_get_u8 bytes sigptr
        let elemTy, sigptr = decodeCustomAttrElemType bytes sigptr et
        mkILArr1DTy elemTy, sigptr
    | x when x = 0x50uy -> PrimaryAssemblyILGlobals.typ_Type, sigptr
    | _ -> failwithf "decodeCustomAttrElemType ilg: unrecognized custom element type: %A" x

/// Given a custom attribute element, encode it to a binary representation according to the rules in Ecma 335 Partition II.
let rec encodeCustomAttrPrimValue c =
    match c with
    | ILAttribElem.Bool b -> [| (if b then 0x01uy else 0x00uy) |]
    | ILAttribElem.String None
    | ILAttribElem.Type None
    | ILAttribElem.TypeRef None
    | ILAttribElem.Null -> [| 0xFFuy |]
    | ILAttribElem.String(Some s) -> encodeCustomAttrString s
    | ILAttribElem.Char x -> u16AsBytes (uint16 x)
    | ILAttribElem.SByte x -> i8AsBytes x
    | ILAttribElem.Int16 x -> i16AsBytes x
    | ILAttribElem.Int32 x -> i32AsBytes x
    | ILAttribElem.Int64 x -> i64AsBytes x
    | ILAttribElem.Byte x -> u8AsBytes x
    | ILAttribElem.UInt16 x -> u16AsBytes x
    | ILAttribElem.UInt32 x -> u32AsBytes x
    | ILAttribElem.UInt64 x -> u64AsBytes x
    | ILAttribElem.Single x -> ieee32AsBytes x
    | ILAttribElem.Double x -> ieee64AsBytes x
    | ILAttribElem.Type(Some ty) -> encodeCustomAttrString ty.QualifiedName
    | ILAttribElem.TypeRef(Some tref) -> encodeCustomAttrString tref.QualifiedName
    | ILAttribElem.Array(_, elems) ->
        [|
            yield! i32AsBytes elems.Length
            for elem in elems do
                yield! encodeCustomAttrPrimValue elem
        |]

and encodeCustomAttrValue ty c =
    match ty, c with
    | ILType.Boxed tspec, _ when tspec.Name = tname_Object ->
        [|
            yield! encodeCustomAttrElemTypeForObject c
            yield! encodeCustomAttrPrimValue c
        |]
    | ILType.Array(shape, _), ILAttribElem.Null when shape = ILArrayShape.SingleDimensional -> [| yield! i32AsBytes 0xFFFFFFFF |]
    | ILType.Array(shape, elemType), ILAttribElem.Array(_, elems) when shape = ILArrayShape.SingleDimensional ->
        [|
            yield! i32AsBytes elems.Length
            for elem in elems do
                yield! encodeCustomAttrValue elemType elem
        |]
    | _ -> encodeCustomAttrPrimValue c

let encodeCustomAttrNamedArg (nm, ty, prop, elem) =
    [|
        yield (if prop then 0x54uy else 0x53uy)
        yield! encodeCustomAttrElemType ty
        yield! encodeCustomAttrString nm
        yield! encodeCustomAttrValue ty elem
    |]

let encodeCustomAttrArgs (mspec: ILMethodSpec) (fixedArgs: _ list) (namedArgs: _ list) =
    let argTys = mspec.MethodRef.ArgTypes

    [|
        yield! [| 0x01uy; 0x00uy |]
        for argTy, fixedArg in Seq.zip argTys fixedArgs do
            yield! encodeCustomAttrValue argTy fixedArg
        yield! u16AsBytes (uint16 namedArgs.Length)
        for namedArg in namedArgs do
            yield! encodeCustomAttrNamedArg namedArg
    |]

let encodeCustomAttr (mspec: ILMethodSpec, fixedArgs, namedArgs) =
    let args = encodeCustomAttrArgs mspec fixedArgs namedArgs
    ILAttribute.Encoded(mspec, args, fixedArgs @ (namedArgs |> List.map (fun (_, _, _, e) -> e)))

let mkILCustomAttribMethRef (mspec: ILMethodSpec, fixedArgs, namedArgs) =
    encodeCustomAttr (mspec, fixedArgs, namedArgs)

let mkILCustomAttribute (tref, argTys, argvs, propvs) =
    encodeCustomAttr (mkILNonGenericCtorMethSpec (tref, argTys), argvs, propvs)

let getCustomAttrData cattr =
    match cattr with
    | ILAttribute.Encoded(_, data, _) -> data
    | ILAttribute.Decoded(mspec, fixedArgs, namedArgs) -> encodeCustomAttrArgs mspec fixedArgs namedArgs

// ILSecurityDecl is a 'blob' having the following format:
// - A byte containing a period (.).
// - A compressed int32 containing the number of attributes encoded in the blob.
// - An array of attributes each containing the following:
// - A String, which is the fully-qualified type name of the attribute. (Strings are encoded
//      as a compressed int to indicate the size followed by an array of UTF8 characters.)
// - A set of properties, encoded as the named arguments to a custom attribute would be (as
//      in §23.3, beginning with NumNamed).
let mkPermissionSet (action, attributes: (ILTypeRef * (string * ILType * ILAttribElem) list) list) =
    let bytes =
        [|
            yield (byte '.')
            yield! z_unsigned_int attributes.Length
            for tref: ILTypeRef, props in attributes do
                yield! encodeCustomAttrString tref.QualifiedName

                let bytes =
                    [|
                        yield! z_unsigned_int props.Length
                        for nm, ty, value in props do
                            yield! encodeCustomAttrNamedArg (nm, ty, true, value)
                    |]

                yield! z_unsigned_int bytes.Length
                yield! bytes
        |]

    ILSecurityDecl.ILSecurityDecl(action, bytes)

// Parse an IL type signature argument within a custom attribute blob
type ILTypeSigParser(tstring: string) =

    let mutable startPos = 0
    let mutable currentPos = 0

    let reset () =
        startPos <- 0
        currentPos <- 0

    let nil = '\r' // cannot appear in a type sig

    // take a look at the next value, but don't advance
    let peek () =
        if currentPos < (tstring.Length - 1) then
            tstring[currentPos + 1]
        else
            nil

    let peekN skip =
        if currentPos < (tstring.Length - skip) then
            tstring[currentPos + skip]
        else
            nil
    // take a look at the current value, but don't advance
    let here () =
        if currentPos < tstring.Length then
            tstring[currentPos]
        else
            nil
    // move on to the next character
    let step () = currentPos <- currentPos + 1
    // ignore the current lexeme
    let skip () = startPos <- currentPos
    // ignore the current lexeme, advance
    let drop () =
        skip ()
        step ()
        skip ()
    // return the current lexeme, advance
    let take () =
        let s =
            if currentPos < tstring.Length then
                tstring[startPos..currentPos]
            else
                ""

        drop ()
        s

    // The format we accept is
    // "<type name>{`<arity>[<type>, +]}{<array rank>}{<scope>}" E.g.,
    //
    // System.Collections.Generic.Dictionary
    //     `2[
    //         [System.Int32, mscorlib, Version=4.0.0.0, Culture=neutral, PublicKeyToken=b77a5c561934e089],
    //         dev.virtualearth.net.webservices.v1.search.CategorySpecificPropertySet],
    // mscorlib, Version=4.0.0.0, Culture=neutral, PublicKeyToken=b77a5c561934e089"
    //
    // Note that
    //   Since we're only reading valid IL, we assume that the signature is properly formed
    //   For type parameters, if the type is non-local, it will be wrapped in brackets ([])
    //   Still needs testing with jagged arrays and byref parameters
    member private x.ParseType() =

        // Does the type name start with a leading '['? If so, ignore it
        // (if the specialization type is in another module, it will be wrapped in bracket)
        if here () = '[' then
            drop ()

        // 1. Iterate over beginning of type, grabbing the type name and determining if it's generic or an array
        let typeName =
            while (peek () <> '`')
                  && (peek () <> '[')
                  && (peek () <> ']')
                  && (peek () <> ',')
                  && (peek () <> nil) do
                step ()

            take ()

        // 2. Classify the type

        // Is the type generic?
        let typeName, specializations =
            if here () = '`' then
                drop () // step to the number
                // fetch the arity
                let arity =
                    while (int (here ()) >= (int '0'))
                          && (int (here ()) <= (int '9'))
                          && (int (peek ()) >= (int '0'))
                          && (int (peek ()) <= (int '9')) do
                        step ()

                    Int32.Parse(take ())
                // skip the '['
                drop ()
                // get the specializations
                typeName + "`" + arity.ToString(),
                Some
                    [
                        for _i in 0 .. arity - 1 do
                            yield x.ParseType()
                    ]
            else
                typeName, None

        // Is the type an array?
        let rank =
            if here () = '[' then
                let mutable rank = 0

                while here () <> ']' do
                    rank <- rank + 1
                    step ()

                drop ()

                Some(ILArrayShape(List.replicate rank (Some 0, None)))
            else
                None

        // Is there a scope?
        let scope =
            if (here () = ',' || here () = ' ') && (peek () <> '[' && peekN 2 <> '[') then
                let grabScopeComponent () =
                    if here () = ',' then
                        drop () // ditch the ','

                    if here () = ' ' then
                        drop () // ditch the ' '

                    while (peek () <> ',' && peek () <> ']' && peek () <> nil) do
                        step ()

                    take ()

                let scope =
                    [
                        yield grabScopeComponent () // assembly
                        yield grabScopeComponent () // version
                        yield grabScopeComponent () // culture
                        yield grabScopeComponent () // public key token
                    ]
                    |> String.concat ","

#if FABLE_COMPILER
                ILScopeRef.Assembly(mkSimpleAssemblyRef scope)
#else
                ILScopeRef.Assembly(ILAssemblyRef.FromAssemblyName(AssemblyName scope))
#endif
            else
                ILScopeRef.Local

        // strip any extraneous trailing brackets or commas
        if (here () = ']') then
            drop ()

        if (here () = ',') then
            drop ()

        // build the IL type
        let tref = mkILTyRef (scope, typeName)

        let genericArgs =
            match specializations with
            | None -> []
            | Some genericArgs -> genericArgs

        let tspec = ILTypeSpec.Create(tref, genericArgs)

        let ilTy =
            match tspec.Name with
            | "System.SByte"
            | "System.Byte"
            | "System.Int16"
            | "System.UInt16"
            | "System.Int32"
            | "System.UInt32"
            | "System.Int64"
            | "System.UInt64"
            | "System.Char"
            | "System.Double"
            | "System.Single"
            | "System.Boolean" -> ILType.Value tspec
            | _ -> ILType.Boxed tspec

        // if it's an array, wrap it - otherwise, just return the IL type
        match rank with
        | Some r -> ILType.Array(r, ilTy)
        | _ -> ilTy

    member x.ParseTypeSpec() =
        reset ()
        let ilTy = x.ParseType()
        ILAttribElem.Type(Some ilTy)

let decodeILAttribData (ca: ILAttribute) =
    match ca with
    | ILAttribute.Decoded(_, fixedArgs, namedArgs) -> fixedArgs, namedArgs
    | ILAttribute.Encoded(_, bytes, _) ->

        let sigptr = 0
        let bb0, sigptr = sigptr_get_byte bytes sigptr
        let bb1, sigptr = sigptr_get_byte bytes sigptr

        if not (bb0 = 0x01 && bb1 = 0x00) then
            failwith "decodeILAttribData: invalid data"

        let rec parseVal argTy sigptr =
            match argTy with
            | ILType.Value tspec when tspec.Name = "System.SByte" ->
                let n, sigptr = sigptr_get_i8 bytes sigptr
                ILAttribElem.SByte n, sigptr
            | ILType.Value tspec when tspec.Name = "System.Byte" ->
                let n, sigptr = sigptr_get_u8 bytes sigptr
                ILAttribElem.Byte n, sigptr
            | ILType.Value tspec when tspec.Name = "System.Int16" ->
                let n, sigptr = sigptr_get_i16 bytes sigptr
                ILAttribElem.Int16 n, sigptr
            | ILType.Value tspec when tspec.Name = "System.UInt16" ->
                let n, sigptr = sigptr_get_u16 bytes sigptr
                ILAttribElem.UInt16 n, sigptr
            | ILType.Value tspec when tspec.Name = "System.Int32" ->
                let n, sigptr = sigptr_get_i32 bytes sigptr
                ILAttribElem.Int32 n, sigptr
            | ILType.Value tspec when tspec.Name = "System.UInt32" ->
                let n, sigptr = sigptr_get_u32 bytes sigptr
                ILAttribElem.UInt32 n, sigptr
            | ILType.Value tspec when tspec.Name = "System.Int64" ->
                let n, sigptr = sigptr_get_i64 bytes sigptr
                ILAttribElem.Int64 n, sigptr
            | ILType.Value tspec when tspec.Name = "System.UInt64" ->
                let n, sigptr = sigptr_get_u64 bytes sigptr
                ILAttribElem.UInt64 n, sigptr
            | ILType.Value tspec when tspec.Name = "System.Double" ->
                let n, sigptr = sigptr_get_ieee64 bytes sigptr
                ILAttribElem.Double n, sigptr
            | ILType.Value tspec when tspec.Name = "System.Single" ->
                let n, sigptr = sigptr_get_ieee32 bytes sigptr
                ILAttribElem.Single n, sigptr
            | ILType.Value tspec when tspec.Name = "System.Char" ->
                let n, sigptr = sigptr_get_u16 bytes sigptr
                ILAttribElem.Char(char (int32 n)), sigptr
            | ILType.Value tspec when tspec.Name = "System.Boolean" ->
                let n, sigptr = sigptr_get_byte bytes sigptr
                ILAttribElem.Bool(n <> 0), sigptr
            | ILType.Boxed tspec when tspec.Name = "System.String" ->
                let n, sigptr = sigptr_get_serstring_possibly_null bytes sigptr
                ILAttribElem.String n, sigptr
            | ILType.Boxed tspec when tspec.Name = "System.Type" ->
                let nOpt, sigptr = sigptr_get_serstring_possibly_null bytes sigptr

                match nOpt with
                | None -> ILAttribElem.TypeRef None, sigptr
                | Some n ->
                    try
                        let parser = ILTypeSigParser n
                        parser.ParseTypeSpec(), sigptr
                    with exn ->
                        failwith (sprintf "decodeILAttribData: error parsing type in custom attribute blob: %s" exn.Message)
            | ILType.Boxed tspec when tspec.Name = "System.Object" ->
                let et, sigptr = sigptr_get_u8 bytes sigptr

                if et = 0xFFuy then
                    ILAttribElem.Null, sigptr
                else
                    let ty, sigptr = decodeCustomAttrElemType bytes sigptr et
                    parseVal ty sigptr
            | ILType.Array(shape, elemTy) when shape = ILArrayShape.SingleDimensional ->
                let n, sigptr = sigptr_get_i32 bytes sigptr

                if n = 0xFFFFFFFF then
                    ILAttribElem.Null, sigptr
                else
                    let rec parseElems acc n sigptr =
                        if n = 0 then
                            List.rev acc, sigptr
                        else
                            let v, sigptr = parseVal elemTy sigptr
                            parseElems (v :: acc) (n - 1) sigptr

                    let elems, sigptr = parseElems [] n sigptr
                    ILAttribElem.Array(elemTy, elems), sigptr
            | ILType.Value _ -> (* assume it is an enumeration *)
                let n, sigptr = sigptr_get_i32 bytes sigptr
                ILAttribElem.Int32 n, sigptr
            | _ -> failwith "decodeILAttribData: attribute data involves an enum or System.Type value"

        let rec parseFixed argTys sigptr =
            match argTys with
            | [] -> [], sigptr
            | h :: t ->
                let nh, sigptr = parseVal h sigptr
                let nt, sigptr = parseFixed t sigptr
                nh :: nt, sigptr

        let fixedArgs, sigptr = parseFixed ca.Method.FormalArgTypes sigptr
        let nnamed, sigptr = sigptr_get_u16 bytes sigptr

        let rec parseNamed acc n sigptr =
            if n = 0 then
                List.rev acc
            else
                let isPropByte, sigptr = sigptr_get_u8 bytes sigptr
                let isProp = (int isPropByte = 0x54)
                let et, sigptr = sigptr_get_u8 bytes sigptr
                // We have a named value
                let ty, sigptr =
                    if ( (* 0x50 = (int et) || *) 0x55 = (int et)) then
                        let qualified_tname, sigptr = sigptr_get_serstring bytes sigptr

                        let unqualified_tname, rest =
                            let pieces = qualified_tname.Split ','

                            if pieces.Length > 1 then
                                pieces[0], Some(String.concat "," pieces[1..])
                            else
                                pieces[0], None

                        let scoref =
                            match rest with
#if FABLE_COMPILER
                            | Some aname -> ILScopeRef.Assembly(mkSimpleAssemblyRef aname)
#else
                            | Some aname -> ILScopeRef.Assembly(ILAssemblyRef.FromAssemblyName(AssemblyName aname))
#endif
                            | None -> PrimaryAssemblyILGlobals.primaryAssemblyScopeRef

                        let tref = mkILTyRef (scoref, unqualified_tname)
                        let tspec = mkILNonGenericTySpec tref
                        ILType.Value tspec, sigptr
                    else
                        decodeCustomAttrElemType bytes sigptr et

                let nm, sigptr = sigptr_get_serstring bytes sigptr
                let v, sigptr = parseVal ty sigptr
                parseNamed ((nm, ty, isProp, v) :: acc) (n - 1) sigptr

        let named = parseNamed [] (int nnamed) sigptr
        fixedArgs, named

// --------------------------------------------------------------------
// Functions to collect up all the references in a full module or
// assembly manifest. The process also allocates
// a unique name to each unique internal assembly reference.
// --------------------------------------------------------------------

type ILReferences =
    {
        AssemblyReferences: ILAssemblyRef[]
        ModuleReferences: ILModuleRef[]
        TypeReferences: ILTypeRef[]
        MethodReferences: ILMethodRef[]
        FieldReferences: ILFieldRef[]
    }

type ILReferencesAccumulator =
    {
        ilg: ILGlobals
        refsA: HashSet<ILAssemblyRef>
        refsM: HashSet<ILModuleRef>
        refsTs: HashSet<ILTypeRef>
        refsMs: HashSet<ILMethodRef>
        refsFs: HashSet<ILFieldRef>
    }

let emptyILRefs =
    {
        AssemblyReferences = [||]
        ModuleReferences = [||]
        TypeReferences = [||]
        MethodReferences = [||]
        FieldReferences = [||]
    }

let refsOfILAssemblyRef (s: ILReferencesAccumulator) x = s.refsA.Add x |> ignore

let refsOfILModuleRef (s: ILReferencesAccumulator) x = s.refsM.Add x |> ignore

let refsOfScopeRef s x =
    match x with
    | ILScopeRef.Local -> ()
    | ILScopeRef.Assembly assemblyRef -> refsOfILAssemblyRef s assemblyRef
    | ILScopeRef.Module modref -> refsOfILModuleRef s modref
    | ILScopeRef.PrimaryAssembly -> refsOfILAssemblyRef s s.ilg.primaryAssemblyRef

let refsOfILTypeRef s (x: ILTypeRef) = refsOfScopeRef s x.Scope

let rec refsOfILType s x =
    match x with
    | ILType.Void
    | ILType.TypeVar _ -> ()
    | ILType.Modified(_, ty1, ty2) ->
        refsOfILTypeRef s ty1
        refsOfILType s ty2
    | ILType.Array(_, ty)
    | ILType.Ptr ty
    | ILType.Byref ty -> refsOfILType s ty
    | ILType.Value tr
    | ILType.Boxed tr -> refsOfILTypeSpec s tr
    | ILType.FunctionPointer mref -> refsOfILCallsig s mref

and refsOfILTypeSpec s (x: ILTypeSpec) =
    refsOfILTypeRef s x.TypeRef
    refsOfILTypes s x.GenericArgs

and refsOfILCallsig s csig =
    refsOfILTypes s csig.ArgTypes
    refsOfILType s csig.ReturnType

and refsOfILGenericParam s x = refsOfILTypes s x.Constraints

and refsOfILGenericParams s b = List.iter (refsOfILGenericParam s) b

and refsOfILMethodRef s (x: ILMethodRef) =
    refsOfILTypeRef s x.DeclaringTypeRef
    refsOfILTypes s x.mrefArgs
    refsOfILType s x.mrefReturn
    s.refsMs.Add x |> ignore

and refsOfILFieldRef s x =
    refsOfILTypeRef s x.DeclaringTypeRef
    refsOfILType s x.Type
    s.refsFs.Add x |> ignore

and refsOfILOverridesSpec s (OverridesSpec(mref, ty)) =
    refsOfILMethodRef s mref
    refsOfILType s ty

and refsOfILMethodSpec s (x: ILMethodSpec) =
    refsOfILMethodRef s x.MethodRef
    refsOfILType s x.DeclaringType
    refsOfILTypes s x.GenericArgs

and refsOfILFieldSpec s x =
    refsOfILFieldRef s x.FieldRef
    refsOfILType s x.DeclaringType

and refsOfILTypes s l = List.iter (refsOfILType s) l

and refsOfILToken s x =
    match x with
    | ILToken.ILType ty -> refsOfILType s ty
    | ILToken.ILMethod mr -> refsOfILMethodSpec s mr
    | ILToken.ILField fr -> refsOfILFieldSpec s fr

and refsOfILCustomAttrElem s (elem: ILAttribElem) =
    match elem with
    | Type(Some ty) -> refsOfILType s ty
    | TypeRef(Some tref) -> refsOfILTypeRef s tref
    | Array(ty, els) ->
        refsOfILType s ty
        refsOfILCustomAttrElems s els
    | _ -> ()

and refsOfILCustomAttrElems s els =
    els |> List.iter (refsOfILCustomAttrElem s)

and refsOfILCustomAttr s (cattr: ILAttribute) =
    refsOfILMethodSpec s cattr.Method
    refsOfILCustomAttrElems s cattr.Elements

and refsOfILCustomAttrs s (cas: ILAttributes) =
    cas.AsArray() |> Array.iter (refsOfILCustomAttr s)

and refsOfILVarArgs s tyso = Option.iter (refsOfILTypes s) tyso

and refsOfILInstr s x =
    match x with
    | I_call(_, mr, varargs)
    | I_newobj(mr, varargs)
    | I_callvirt(_, mr, varargs) ->
        refsOfILMethodSpec s mr
        refsOfILVarArgs s varargs
    | I_callconstraint(_, _, tr, mr, varargs) ->
        refsOfILType s tr
        refsOfILMethodSpec s mr
        refsOfILVarArgs s varargs
    | I_calli(_, callsig, varargs) ->
        refsOfILCallsig s callsig
        refsOfILVarArgs s varargs
    | I_jmp mr
    | I_ldftn mr
    | I_ldvirtftn mr -> refsOfILMethodSpec s mr
    | I_ldsfld(_, fr)
    | I_ldfld(_, _, fr)
    | I_ldsflda fr
    | I_ldflda fr
    | I_stsfld(_, fr)
    | I_stfld(_, _, fr) -> refsOfILFieldSpec s fr
    | I_isinst ty
    | I_castclass ty
    | I_cpobj ty
    | I_initobj ty
    | I_ldobj(_, _, ty)
    | I_stobj(_, _, ty)
    | I_box ty
    | I_unbox ty
    | I_unbox_any ty
    | I_sizeof ty
    | I_ldelem_any(_, ty)
    | I_ldelema(_, _, _, ty)
    | I_stelem_any(_, ty)
    | I_newarr(_, ty)
    | I_mkrefany ty
    | I_refanyval ty
    | EI_ilzero ty -> refsOfILType s ty
    | I_ldtoken token -> refsOfILToken s token
    | I_stelem _
    | I_ldelem _
    | I_ldstr _
    | I_switch _
    | I_stloc _
    | I_stind _
    | I_starg _
    | I_ldloca _
    | I_ldloc _
    | I_ldind _
    | I_ldarga _
    | I_ldarg _
    | I_leave _
    | I_br _
    | I_brcmp _
    | I_rethrow
    | I_refanytype
    | I_ldlen
    | I_throw
    | I_initblk _
    | I_cpblk _
    | I_localloc
    | I_ret
    | I_endfilter
    | I_endfinally
    | I_arglist
    | I_break
    | AI_add
    | AI_add_ovf
    | AI_add_ovf_un
    | AI_and
    | AI_div
    | AI_div_un
    | AI_ceq
    | AI_cgt
    | AI_cgt_un
    | AI_clt
    | AI_clt_un
    | AI_conv _
    | AI_conv_ovf _
    | AI_conv_ovf_un _
    | AI_mul
    | AI_mul_ovf
    | AI_mul_ovf_un
    | AI_rem
    | AI_rem_un
    | AI_shl
    | AI_shr
    | AI_shr_un
    | AI_sub
    | AI_sub_ovf
    | AI_sub_ovf_un
    | AI_xor
    | AI_or
    | AI_neg
    | AI_not
    | AI_ldnull
    | AI_dup
    | AI_pop
    | AI_ckfinite
    | AI_nop
    | AI_ldc _
    | I_seqpoint _
    | EI_ldlen_multi _ -> ()

and refsOfILCode s (c: ILCode) =
    for i in c.Instrs do
        refsOfILInstr s i

    for exnClause in c.Exceptions do
        match exnClause.Clause with
        | ILExceptionClause.TypeCatch(ilTy, _) -> refsOfILType s ilTy
        | _ -> ()

and refsOfILMethodBody s (il: ILMethodBody) =
    List.iter (refsOfILLocal s) il.Locals
    refsOfILCode s il.Code

and refsOfILLocal s loc = refsOfILType s loc.Type

and refsOfMethodBody s x =
    match x with
    | MethodBody.IL il -> refsOfILMethodBody s il.Value
    | MethodBody.PInvoke attr -> refsOfILModuleRef s attr.Value.Where
    | _ -> ()

and refsOfILMethodDef s (md: ILMethodDef) =
    List.iter (refsOfILParam s) md.Parameters
    refsOfILReturn s md.Return
    refsOfMethodBody s md.Body
    refsOfILCustomAttrs s md.CustomAttrs
    refsOfILGenericParams s md.GenericParams

and refsOfILParam s p = refsOfILType s p.Type

and refsOfILReturn s (rt: ILReturn) = refsOfILType s rt.Type

and refsOfILMethodDefs s x = Seq.iter (refsOfILMethodDef s) x

and refsOfILEventDef s (ed: ILEventDef) =
    Option.iter (refsOfILType s) ed.EventType
    refsOfILMethodRef s ed.AddMethod
    refsOfILMethodRef s ed.RemoveMethod
    Option.iter (refsOfILMethodRef s) ed.FireMethod
    List.iter (refsOfILMethodRef s) ed.OtherMethods
    refsOfILCustomAttrs s ed.CustomAttrs

and refsOfILEventDefs s (x: ILEventDefs) =
    List.iter (refsOfILEventDef s) (x.AsList())

and refsOfILPropertyDef s (pd: ILPropertyDef) =
    Option.iter (refsOfILMethodRef s) pd.SetMethod
    Option.iter (refsOfILMethodRef s) pd.GetMethod
    refsOfILType s pd.PropertyType
    refsOfILTypes s pd.Args
    refsOfILCustomAttrs s pd.CustomAttrs

and refsOfILPropertyDefs s (x: ILPropertyDefs) =
    List.iter (refsOfILPropertyDef s) (x.AsList())

and refsOfILFieldDef s (fd: ILFieldDef) =
    refsOfILType s fd.FieldType
    refsOfILCustomAttrs s fd.CustomAttrs

and refsOfILFieldDefs s fields = List.iter (refsOfILFieldDef s) fields

and refsOfILMethodImpls s mimpls = List.iter (refsOfILMethodImpl s) mimpls

and refsOfILMethodImpl s m =
    refsOfILOverridesSpec s m.Overrides
    refsOfILMethodSpec s m.OverrideBy

and refsOfILTypeDef s (td: ILTypeDef) =
    refsOfILTypeDefs s td.NestedTypes
    refsOfILGenericParams s td.GenericParams
    refsOfILTypes s (td.Implements.Value |> List.map _.Type)
    Option.iter (refsOfILType s) td.Extends.Value
    refsOfILMethodDefs s td.Methods
    refsOfILFieldDefs s (td.Fields.AsList())
    refsOfILMethodImpls s (td.MethodImpls.AsList())
    refsOfILEventDefs s td.Events
    refsOfILCustomAttrs s td.CustomAttrs
    refsOfILPropertyDefs s td.Properties

and refsOfILTypeDefs s (types: ILTypeDefs) = Seq.iter (refsOfILTypeDef s) types

and refsOfILExportedType s (c: ILExportedTypeOrForwarder) = refsOfILCustomAttrs s c.CustomAttrs

and refsOfILExportedTypes s (tab: ILExportedTypesAndForwarders) =
    List.iter (refsOfILExportedType s) (tab.AsList())

and refsOfILResourceLocation s x =
    match x with
    | ILResourceLocation.Local _ -> ()
    | ILResourceLocation.File(mref, _) -> refsOfILModuleRef s mref
    | ILResourceLocation.Assembly aref -> refsOfILAssemblyRef s aref

and refsOfILResource s x =
    refsOfILResourceLocation s x.Location
    refsOfILCustomAttrs s x.CustomAttrs

and refsOfILResources s (tab: ILResources) =
    List.iter (refsOfILResource s) (tab.AsList())

and refsOfILModule s m =
    refsOfILTypeDefs s m.TypeDefs
    refsOfILResources s m.Resources
    refsOfILCustomAttrs s m.CustomAttrs
    Option.iter (refsOfILManifest s) m.Manifest

and refsOfILManifest s (m: ILAssemblyManifest) =
    refsOfILCustomAttrs s m.CustomAttrs
    refsOfILExportedTypes s m.ExportedTypes

let computeILRefs ilg modul =
    let s =
        {
            ilg = ilg
            refsA = HashSet<_>(HashIdentity.Structural)
            refsM = HashSet<_>(HashIdentity.Structural)
            refsTs = HashSet<_>(HashIdentity.Structural)
            refsMs = HashSet<_>(HashIdentity.Structural)
            refsFs = HashSet<_>(HashIdentity.Structural)
        }

    refsOfILModule s modul

    {
#if FABLE_COMPILER
        AssemblyReferences = s.refsA |> Seq.toArray
        ModuleReferences = s.refsM |> Seq.toArray
        TypeReferences = s.refsTs |> Seq.toArray
        MethodReferences = s.refsMs |> Seq.toArray
        FieldReferences = s.refsFs |> Seq.toArray
#else
        AssemblyReferences = s.refsA.ToArray()
        ModuleReferences = s.refsM.ToArray()
        TypeReferences = s.refsTs.ToArray()
        MethodReferences = s.refsMs.ToArray()
        FieldReferences = s.refsFs.ToArray()
#endif
    }

let unscopeILTypeRef (x: ILTypeRef) =
    ILTypeRef.Create(ILScopeRef.Local, x.Enclosing, x.Name)

let rec unscopeILTypeSpec (tspec: ILTypeSpec) =
    let tref = tspec.TypeRef
    let tinst = tspec.GenericArgs
    let tref = unscopeILTypeRef tref
    ILTypeSpec.Create(tref, unscopeILTypes tinst)

and unscopeILType ty =
    match ty with
    | ILType.Ptr t -> ILType.Ptr(unscopeILType t)
    | ILType.FunctionPointer t -> ILType.FunctionPointer(unscopeILCallSig t)
    | ILType.Byref t -> ILType.Byref(unscopeILType t)
    | ILType.Boxed cr -> mkILBoxedType (unscopeILTypeSpec cr)
    | ILType.Array(s, ty) -> ILType.Array(s, unscopeILType ty)
    | ILType.Value cr -> ILType.Value(unscopeILTypeSpec cr)
    | ILType.Modified(b, tref, ty) -> ILType.Modified(b, unscopeILTypeRef tref, unscopeILType ty)
    | x -> x

and unscopeILTypes i =
    if List.isEmpty i then i else List.map unscopeILType i

and unscopeILCallSig csig =
    mkILCallSig (csig.CallingConv, unscopeILTypes csig.ArgTypes, unscopeILType csig.ReturnType)

let resolveILMethodRefWithRescope r (td: ILTypeDef) (mref: ILMethodRef) =
    let args = mref.ArgTypes
    let nargs = args.Length
    let nm = mref.Name
    let possibles = td.Methods.FindByNameAndArity(nm, nargs)

    if isNil possibles then
        failwith ("no method named " + nm + " found in type " + td.Name)

    let argTypes = mref.ArgTypes |> List.map r
    let retType: ILType = r mref.ReturnType

    match
        possibles
        |> List.filter (fun md ->
            mref.CallingConv = md.CallingConv
            && (md.Parameters, argTypes)
               ||> List.lengthsEqAndForall2 (fun p1 p2 -> r p1.Type = p2)
            && md.GenericParams.Length = mref.GenericArity
            &&
            // REVIEW: this uses equality on ILType. For CMOD_OPTIONAL this is not going to be correct
            r md.Return.Type = retType)
    with
    | [] ->
        failwith (
            "no method named "
            + nm
            + " with appropriate argument types found in type "
            + td.Name
        )
    | [ mdef ] -> mdef
    | _ ->
        failwith (
            "multiple methods named "
            + nm
            + " appear with identical argument types in type "
            + td.Name
        )

let resolveILMethodRef td mref =
    resolveILMethodRefWithRescope id td mref

let mkRefToILModule m = ILModuleRef.Create(m.Name, true, None)

type ILEventRef =
    {
        erA: ILTypeRef
        erB: string
    }

    static member Create(a, b) = { erA = a; erB = b }

    member x.DeclaringTypeRef = x.erA

    member x.Name = x.erB

type ILPropertyRef =
    {
        prA: ILTypeRef
        prB: string
    }

    static member Create(a, b) = { prA = a; prB = b }

    member x.DeclaringTypeRef = x.prA

    member x.Name = x.prB
